Your search keyword '"E.G. Yaroslavova"' showing total 9 results

1. Variable and low-toxic polyampholytes: complexation with biological membranes

Author

Andrey V. Sybachin, Nikolay S. Melik-Nubarov, T. A. Sitnikova, E.G. Yaroslavova, A. A. Rakhnyanskaya, Gennady B. Khomutov, and Alexander A. Yaroslavov

Subjects

chemistry.chemical_classification, Liposome, Polymers and Plastics, Cationic polymerization, Biological membrane, 02 engineering and technology, Degree of polymerization, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Polyelectrolyte, 0104 chemical sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, Betaine, Membrane, chemistry, Polymer chemistry, Materials Chemistry, Organic chemistry, Physical and Theoretical Chemistry, 0210 nano-technology, Alkyl

Abstract

In this paper, we describe three series of polyampholytes synthesized via quaternization of poly(4-vinylpyridin) by ω-bromocarboxylic acids and alkyl bromides: (1) with cationic and anionic groups in each unit (polybetaines), (2) with betaine and cationic groups, and (3) with betaine and pendant alkyl groups. The polymers were complexed with anionic mixed lipid membranes, liposomes, and Langmuir monolayers. By varying a length of –(CH2)n– spacer in the betaine group, different behaviors of polybetaines in a suspension of anionic liposomes can be realized: from no interaction to complexation followed by significant structural reorganization in the liposomal membrane. Cytotoxicities of polyampholytes are one to two orders of magnitude less than the cytotoxicity of a pure polycationic polymer with the same degree of polymerization. These results are of importance in designing polyelectrolytes with a higher affinity to the biolodical (cell) membrane and minimum cytotoxicity and demonstrate the potential of polyampholytes in developing biocompatible polymeric structures.

Published

2017

2. Physicochemical and biological properties of polyampholytes: Quaternized derivatives of poly(4-vinylpyridine)

Author

E.G. Yaroslavova, N. S. Melik-Nubarov, Alexander A. Yaroslavov, T. A. Sitnikova, and A. A. Rakhnyanskaya

Subjects

chemistry.chemical_classification, Liposome, Polymers and Plastics, Cationic polymerization, Degree of polymerization, Polyelectrolyte, chemistry.chemical_compound, Betaine, Monomer, chemistry, Polymer chemistry, Materials Chemistry, Organic chemistry, Lipid bilayer, Alkyl

Abstract

The modification of poly(4-vinylpyridine) with ω-bromocarboxylic acids and alkyl bromides yields three types of polyampholytes: polyampholytes containing both cationic and anionic groups in each monomer unit (polybetaines), polyampholytes containing betaine and cationic units, and polyampholytes containing betaine units and side cetyl radicals. Their complex formation with liposomes formed from zwitterionic (electroneutral) phosphatidylcholine and anionic diphosphatidylglycerol (cardiolipin) is investigated. The method for fixation of polymers on the liposomal membrane and the stability of the formed complexes are determined by the chemical structure of macromolecules. For the most part, polyelectrolytes are electrostatically adsorbed on the membrane and are fully removed from it with an increase in the salt concentration in the surrounding solution. An exception is the polybetaine obtained through the modification of poly(4-vinylpyridine) with ω-bromobutyric acid, which irreversibly binds to liposomes probably owing to the incorporation of macromolecular fragments into the hydrophobic part of the lipid bilayer. The insertion of side cetyl radicals into polybetaine molecules stabilizes their complexes with liposomes in the presence of salts. The cytotoxicity of the synthesized polyampholytes is one to two orders of magnitude lower than that of a cationic polymer with the same degree of polymerization.

Published

2013

3. Polymer Migration among Phospholipid Liposomes

Author

E.G. Yaroslavova, A. A. Efimova, Fredric M. Menger, Alexander A. Yaroslavov, A. A. Rakhnyanskaya, Yury A. Ermakov, and D. A. Davydov

Subjects

Egg lecithin, Liposome, Cardiolipins, Polymers, Chemistry, Phospholipid, Cationic polymerization, Ether, Surfaces and Interfaces, Condensed Matter Physics, Quaternary Ammonium Compounds, chemistry.chemical_compound, Models, Chemical, Bromide, Phosphatidylcholine, Liposomes, Polymer chemistry, Phosphatidylcholines, Electrochemistry, Organic chemistry, General Materials Science, Phospholipids, Spectroscopy, Macromolecule

Abstract

Complexation of phospholipid lipsomes with a cationic polymer, poly(N-ethyl-4-vinylpyridinium bromide) (PEVP), and subsequent interliposomal migration of the adsorbed macromolecules, have been investigated. Liposomes of two different charge types were examined: (a) a liposomal system, with an overall charge near zero, consisting of zwitterionic phosphatidylcholine (egg lecithin, EL) with added doubly anionic phospholipid, cardiolipin (CL(2-)), and cationic dihexadecyldimethylammonium bromide (HMAB(+)), in a CL(2-)/HMAB(+) charge-to-charge ratio of 1:1; (b) an anionic liposomal system composed of an EL/CL(2-) mixture plus polyoxyethylene monocetyl ether (Brij 58). Both three-component systems were designed specifically to preclude liposomal aggregation upon electrostatic association with the PEVP, a phenomenon that had complicated analysis of data from several two-component liposomes. PEVP macromolecules were found from fluorescence experiments to migrate among the charge-neutral EL/CL(2-)/HMAB(+) liposomes. In the case of anionic EL/CL(2-)/Brij liposomes, a combination of fluorescence and laser microelectrophoresis methods showed that PEVP macromolecules travel from liposome to liposome while being electrostatically associated with anionic lipids.

Published

2009

4. Structure and characteristics of the complexes between polyampholites and anionic liposomes

Author

T. A. Sitnikova, A.N. Sergeev-Cherenkov, V. Ya. Grinberg, Alexander A. Yaroslavov, Gennady B. Khomutov, A. A. Rakhnyanskaya, Tatiana V. Burova, and E.G. Yaroslavova

Subjects

Liposome, Polymers and Plastics, Bilayer, Membrane lipids, Phospholipid, Cationic polymerization, chemistry.chemical_compound, Membrane, Betaine, chemistry, Zwitterion, Polymer chemistry, Materials Chemistry, Organic chemistry, lipids (amino acids, peptides, and proteins)

Abstract

Polyampholites are synthesized by the alkylation of poly-4-vinylpyridine with ω-bromocarboxylic acids, and their interaction with the negatively charged bilayer lipid vesicles (liposomes) is studied. In the above polymers, quaternized pyridine units are zwitterion (betaine) groups, in which cationic and anionic groups are linked by the -(CH2)n-bridges. Via the methods of fluorescence, laser scattering, and DSC, the length of the ethylene spacer in the betaine group is shown to control the ability of the polymer to interact with anionic liposomes and induce structural rearrangements in the liposomal membrane. At n = 1, polybetaine is not linked to anionic liposomes. At n = 2, polybetaine is sorbed on the membrane, but it causes no dramatic structural rearrangements in the bilayer. At n = 3, the adsorption of polybetaine triggers the lateral segregation of lipids in the outer membrane layer. At n = 5, adsorption of polymer is accompanied by the lateral segregation and flip-flop of lipid molecules; as a result, all anionic membrane lipids are involved in the microphase separation. This evidence is of evident interest for the controlled design of polymers and related complexes and conjugates for biomedical applications.

Published

2009

5. Migration of a cationic polymer between lipid vesicles

Author

D. A. Davydov, E.G. Yaroslavova, A. A. Efimova, and Alexander A. Yaroslavov

Subjects

Liposome, Ethylene oxide, Vesicle, Bilayer, Cationic polymerization, Ether, Surfaces and Interfaces, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Bromide, Phosphatidylcholine, Polymer chemistry, Organic chemistry, Physical and Theoretical Chemistry

Abstract

The adsorption of a synthetic polycation, poly(N-ethyl-4-vinylpyridinium bromide) (PEVP), on the surface of bilayer lipid vesicles (liposomes) and the migration of adsorbed macromolecules between the liposomes are studied. Liposomes of three types are used, including (1) traditional two-component liposomes composed of neutral phosphatidylcholine (PC) and anionic cardiolipin (CL); (2) three-component liposomes consisting of PC, CL, and cationic dicetyldimethylammonium bromide (DCMAB); and (3) anionic PC/CL liposomes with a nonionic surfactant, poly(ethylene oxide)-cetyl alcohol ether (Briij 58), incorporated into their bilayers. The adsorption of PEVP on the surface of PC/CL liposomes is accompanied by their aggregation. Using the fluorescence method, it is shown that the units (segments) of the polycation undergo partial redistribution between the liposomes inside the aggregates formed from PC/CL liposomes (with and without a fluorescent label) and PEVP. On the contrary, three-component PC/CL/DCMAB and PC/CL/Briij liposomes are not aggregated, even with the complete neutralization of their charges by adsorbed PEVP. In both cases, the migration of PEVP molecules between individual (nonaggregated) liposomes is observed. Possible reasons for the aggregative stability of the three-component PC/CL/DCMAB and PC/CL/Briij liposomes and the mechanism of interliposome migration of PEVP in such systems are discussed.

Published

2009

6. Polyelectrolyte-coated liposomes: Stabilization of the interfacial complexes

Author

E.G. Yaroslavova, Alexander A. Yaroslavov, A. A. Efimova, A. A. Rakhnyanskaya, and Fredric M. Menger

Subjects

Egg lecithin, Liposome, Conductometry, Polymers, Bilayer, Polyacrylic acid, Surfaces and Interfaces, Polyelectrolyte, Absorption, Electrolytes, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Dipalmitoylphosphatidylcholine, Liposomes, Polymer chemistry, Organic chemistry, Particle Size, Physical and Theoretical Chemistry, Lipid bilayer, Hydrophobic and Hydrophilic Interactions

Abstract

Anionic liposomes, composed of egg lecithin (EL) or dipalmitoylphosphatidylcholine (DPPC) with 20 mol% of cardiolipin (CL(2-)), were mixed with cationic polymers, poly(4-vinylpyridine) fully quaternized with ethyl bromide (P2) or poly-L-lysine (PL). Polymer/liposome binding studies were carried out using electrophoretic mobility (EPM), fluorescence, and conductometry as the main analytical tools. Binding was also examined in the presence of added salt and polyacrylic acid (PAA). The following generalizations arose from the experiments: (a) Binding of P2 and PL to small EL/CL(2-) liposomes (60-80 nm in diameter) is electrostatic in nature and completely reversed by addition of salt or PAA. (b) Binding can be enhanced by hydrophobization of the polymer with cetyl groups. (c) Binding can also be enhanced by changing the phase state of the lipid bilayer from liquid to solid (i.e. going from EL to DPPC) or by increasing the size of the liposomes (i.e. going from 60-80 to 300 nm). By far the most promising systems, from the point of view of constructing polyelectrolyte multilayers on liposome cores without disruption of liposome integrity, involve small, liquid, anionic liposomes coated initially with polycations carrying pendant alkyl groups.

Published

2008

7. Modulation of interaction of polycations with negative unilamellar lipid vesicles

Author

E.G. Yaroslavova, Fredric M. Menger, A. A. Rakhnyanskaya, Victor A. Kabanov, and Alexander A. Yaroslavov

Subjects

Bilayer, Vesicle, Polyacrylic acid, Surfaces and Interfaces, General Medicine, Polyelectrolyte, Hydrophobic effect, chemistry.chemical_compound, Hydrophilic-lipophilic balance, Colloid and Surface Chemistry, Membrane, chemistry, Polymer chemistry, Organic chemistry, Physical and Theoretical Chemistry, Lipid bilayer, Biotechnology

Abstract

Interactions of small unilamellar negative vesicles composed of diphosphatidylglycerol (cardiolipin, CL2−), 20 mol%, and phosphatidylcholine (egg yolk lecithin, EL), 80 mol%, with various cationic polymers (CP) derived from poly(4-vinylpyridine) (PVP) were studied in water and water–salt solutions by means of photon correlation spectroscopy, microelectrophoresis, conductometry, and fluorescence techniques. The linear charge density and hydrophilic lipophilic balance of CPs were varied by quaternization of PVP with various amounts of different alkyl bromides (ethyl-(2), heptyl-(7), dodecyl-(12), cetyl-(16)). Substantial differences were observed in the behavior of exhaustingly N-ethylated PVP (CP2) and PVP N-ethylated to 50 mol% (CP2(50)) or 30 mol% (CP2(30)). All of them adsorb to the CL2−/EL vesicle membrane, neutralizing the surface negative charge and causing aggregation of the vesicles. However, CP2, a polycation with a maximum linear charge density, strongly enhances transfer of the negative lipid ions from the inner to outer bilayer leaflet, while CP2(50) and CP2(30) do not. Adsorbed CP2 does not disturb integrity of the vesicle membrane and can be completely removed from the surface of aggregated vesicles by adding a simple salt (NaCl) or a negative linear polyelectrolyte (polyacrylic acid (PAA) sodium salt). Such removal is followed by release of the original vesicles. In contrast to that, adsorbed CP2(50) or CP2(30) produce some leak through the lipid bilayer and cannot be completely desorbed either by increasing ionic strength or adding an excess of PAA. The probable reason of these differences is discussed. PVP partially N-alkylated with dodecyl or cetyl bromides (3 mol%) and then completely N-ethylated (CP2,12 and CP2,16), also having a maximum linear charge density, adsorbs to the negative vesicle surface as a result of both electrostatic binding and hydrophobic interaction. Bulky hydrocarbon pendant groups incorporate into the inner bilayer compartment. Similarly to CP2(50) and CP2(30), CP2,12 and CP2,16 cannot be removed from the surface either by adding the simple salt, or an excess of PAA. However, in contrast to CP2(50) and CP2(30), the polycations with the bulky hydrocarbon pendant groups do not cause any leak through the vesicle membrane. Finally, we have succeeded to prepare the ternary vesicles also composed of 20 mol% of CL2−, but partially replacing EL for polyoxyethylene 20 cetyl ether (Brij 58) (up to 30 mol%). The CL2−/EL/Brij vesicle carries a hydrophilic corona formed by polyoxyethylene chains exposed into water, while hydrophobic cetyl radicals are incorporated in the lipid bilayer. The CL2−/EL/Brij vesicles adsorb all studied CPs similar to the binary CL2−/EL vesicles. This means that polyoxyethylene corona is permeable for polycationic species restricting neither electrostatic binding nor incorporation of bulky hydrocarbon groups of CP2,16 into the membrane. However, the corona effectively stabilizes the CP-vesicle complexes against aggregation when the membrane surface is neutralized.

Published

1999

8. Competitive Interactions in Negatively Charged Liposome−Polycation−Polyanion Ternary Systems

Author

V. Y. Koulkov, Alexander A. Yaroslavov, E.G. Yaroslavova, Victor A. Kabanov, Fredric M. Menger, and M. O. Ignatiev

Subjects

Liposome, Aqueous solution, Conductometry, Chemistry, Surfaces and Interfaces, Condensed Matter Physics, Polyelectrolyte, chemistry.chemical_compound, Bromide, Ionic strength, Phosphatidylcholine, Polymer chemistry, Electrochemistry, Organic chemistry, General Materials Science, Ternary complex, Spectroscopy

Abstract

This paper involves small unilamellar liposomes (SULs) of phosphatidylcholine (PC) imparted with a negative charge via the incorporation of cardiolipin (CL 2- ), a lipid with a double-negative charge. Such liposomes in water strongly adsorb polycations such as CP(2)(a 93/7 copolymer ofN-ethyl-4-vinylpyridinium bromide and 4-vinylpyridine) or CP(2,16) (a 83/3/14 copolymer of N-ethyl-4-vinylpyridinium bromide, N-cetyl-4-vinylpyridinium bromide, and 4-vinylpyridine). Neither CP(2) nor CP(2,16) disrupts the integrity of the PC-CL 2- liposome despite the tight binding. Addition of NaCl is able to totally dissociate CP(2) from the negative SULs, whereas CP(2,16) is only partially dissociated even at high salt concentrations. Thus, only 3% long-chain pendant groups on the polycation is sufficient to immobilize the polycation onto the negative surface of SULs. Similarly, poly(acrylic acid) (PAA) in its anionic state will remove CP(2) from the liposome surface to form a CP(2)-PAA complex. CP(2,16), on the other hand, is more resistant to removal. Evidence is provided that the CP(2,16) associates with PAA but nonetheless remains on the surface of the liposome. Thus, a liposome-CP(2,16)-PAA ternary complex is created. This work makes heavy use of photon correlation spectroscopy, conductometry, electrophoretic mobility, and fluorescent labeling of the liposomes.

Published

1998

9. What is the effective charge of TGA-stabilized CdTe nanocolloids?

Author

A. A. Rakhnyanskaya, E.G. Yaroslavova, Yury A. Ermakov, Nicholas A. Kotov, A. A. Efimova, Alexander A. Yaroslavov, and Vladimir A. Sinani

Subjects

Aqueous solution, Chemistry, Fluorescence spectrometry, Analytical chemistry, Charge density, General Chemistry, Biochemistry, Catalysis, Effective nuclear charge, Polyelectrolyte, Ion, Colloid and Surface Chemistry, Adsorption, Surface charge

Abstract

The surface charge of semiconductor nanoparticles, Q, is an important parameter which determines their electrokinetic behavior, stability in water and polar solvents, functions of optical and electronic devices, self-assembly properties, and interactions with cell membranes. We have developed a simple method for quantitative determination of Q in their native aqueous environment. The method does not require the knowledge of exact atomic structure or make assumptions about effects of drying on charge distribution. The method is based on titration of nanoparticle dispersion with a solution of oppositely charged polyelectrolyte. The point of complete neutralization is recognized as an inflection point on the dependence of fluorescence intensity on the amount of polyelectrolyte added. Thioglycolic acid-stabilized CdTe nanoparticles 2 nm in diameter were found to carry an average Q from -2.6 to -5.5 for pH 7.5 to 10, respectively. This charge is found to be smaller than that calculated theoretically for an analogous structure (i.e., Q = -8), presumably due to adsorption of Cd(2+) ions on the stabilizer shell and on Te atoms with unsaturated valence located on the side planes of CdTe tetrahedrons.

Published

2005