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Ефективні радіуси макромолекул альбуміну людини із даних по зсувній в’язкості його водних розчинів

Ефективні радіуси макромолекул альбуміну людини із даних по зсувній в’язкості його водних розчинів

The Malomuzh–Orlov theory is used to analyze the experimental shear viscosity data obtained for aqueous solutions of human serum albumin (HSA) at pH = 7.0 in wide temperature and concentration intervals, which allowed the effective radii of HSA macromolecules to be calculated. It is shown that three...

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Bibliographic Details
Main Author: Khorolskyi, O. V.
Format: Article
Language:English
Ukrainian
Published: Publishing house "Academperiodika" 2019
Subjects:
сироватковий альбумiн людини
водний розчин
ефективний радiус макромолекули
теорiя Маломужа—Орлова
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human serum albumin
aqueous solution
effective macromolecular radius
Malomuzh–Orlov theory
Online Access:https://ujp.bitp.kiev.ua/index.php/ujp/article/view/2019314
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Summary:The Malomuzh–Orlov theory is used to analyze the experimental shear viscosity data obtained for aqueous solutions of human serum albumin (HSA) at pH = 7.0 in wide temperature and concentration intervals, which allowed the effective radii of HSA macromolecules to be calculated. It is shown that three intervals of the effective molecular radius of HSA with different behaviors can be distinguished in a temperature interval of 278–318 K: 1) below the crossover concentration, the effective molecular radius of HSA remains constant; 2) in the interval from the crossover concentration to about 10 wt%, the effective molecular radius of HSA in the aqueous solution nonlinearly decreases; and 3) at concentrations of 10.2–23.8 wt%, the effective radius of HSA macromolecules linearly decreases, as the concentration grows. The assumption is made that the properties of water molecules in the solution bulk play a crucial role in the dynamics of HSA macromolecules at the vital concentrations of HSA in the solutions. The role of water near the surface of HSA macromolecules and the corresponding changes of its physical properties have been discussed.

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