Andrey A Gurtovenko
Overview
Explore the profile of Andrey A Gurtovenko including associated specialties, affiliations and a list of published articles.
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44
Citations
738
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Recent Articles
1.
Glova A, Nazarychev V, Larin S, Gurtovenko A, Lyulin S
Phys Chem Chem Phys
. 2023 Nov;
25(46):32196-32207.
PMID: 37987172
Recent experiments and atomistic computer simulations have shown that asphaltene byproducts of oil refineries can serve as thermal conductivity enhancers for organic phase-change materials such as paraffin and therefore have...
2.
Gurtovenko A, Nazarychev V, Glova A, Larin S, Lyulin S
J Chem Phys
. 2023 Jun;
158(23).
PMID: 37318174
Asphaltenes represent a novel class of carbon nanofillers that are of potential interest for many applications, including polymer nanocomposites, solar cells, and domestic heat storage devices. In this work, we...
3.
Nazarychev V, Glova A, Larin S, Lyulin A, Lyulin S, Gurtovenko A
Int J Mol Sci
. 2022 Dec;
23(23).
PMID: 36498903
A molecular-level insight into phase transformations is in great demand for many molecular systems. It can be gained through computer simulations in which cooling is applied to a system at...
4.
Elucidating lipid conformations in the ripple phase: Machine learning reveals four lipid populations
Davies M, Reyes-Figueroa A, Gurtovenko A, Frankel D, Karttunen M
Biophys J
. 2022 Nov;
122(2):442-450.
PMID: 36403088
A new mixed radial-angular, three-particle correlation function method in combination with unsupervised machine learning was applied to examine the emergence of the ripple phase in dipalmitoylphosphatidylcholine (DPPC) lipid bilayers using...
5.
Glova A, Volgin I, Nazarychev V, Larin S, Lyulin S, Gurtovenko A
RSC Adv
. 2022 May;
9(66):38834-38847.
PMID: 35540183
Paraffin-based composites represent a promising class of materials with numerous practical applications such as heat storage. Computer modeling of these complex multicomponent systems requires a proper theoretical description of both...
6.
Volgin I, Glova A, Nazarychev V, Larin S, Lyulin S, Gurtovenko A
RSC Adv
. 2022 May;
10(52):31316-31317.
PMID: 35532387
[This corrects the article DOI: 10.1039/C9RA07325F.].
7.
Gurtovenko A, Karttunen M
Soft Matter
. 2021 Jun;
17(27):6507-6518.
PMID: 34100057
Being able to control the interactions of biomaterials with living tissues and skin is highly desirable for many biomedical applications. This is particularly the case for cellulose-based materials which provide...
8.
Gurtovenko A, Karttunen M
Langmuir
. 2019 Sep;
35(42):13753-13760.
PMID: 31553618
Controlling interactions between cellulose-based materials and membranes of living cells is critical in medicine and biotechnology in, for example, wound dressing, tissue engineering, hemodialysis membranes, and drug transport. Cellulose acetylation...
9.
Gurtovenko A
J Phys Chem B
. 2019 Jul;
123(30):6505-6514.
PMID: 31290315
The interactions of DNA/polycation complexes (polyplexes) with cell membranes are crucial for understanding the molecular mechanisms behind polycation-mediated delivery of nucleic acid therapeutics into the target cells. In this study,...
10.
Gurtovenko A, Javanainen M, Lolicato F, Vattulainen I
J Phys Chem Lett
. 2019 Feb;
10(5):1005-1011.
PMID: 30768280
Single-particle tracking (SPT) is an experimental technique that allows one to follow the dynamics of individual molecules in biological membranes with unprecedented precision. Given the importance of lipid and membrane...