Lozinskiy V.I., Antonov Yu.A., Damshkaln L.G., Ezernitskaya M.G., Glotova Yu.K. Wide-Pore Cryogels Prepared Using the Combination of Liquid-Liquid Phase Separation and Cryotropic Gel-Formation Processes
WIDE-PORE CRYOGELS PREPARED USING THE COMBINATION OF LIQUID-LIQUID PHASE SEPARATION AND CRYOTROPIC GEL-FORMATION PROCESSES
Vladimir Iosifovich Lozinskiy
Doctor of Chemical Sciences, Professor,
Head of Laboratory for Cryochemistry of (Bio)Polymers,
A. N. Nesmeyanov Institute of Organoelement Compounds, RAS
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Vavilova St., 28, 119991 Moscow, Russian Federation
Yuriy Alekseevich Antonov
Doctor of Biological Sciences, Professor, Researcher,
Institute of Biochemical Physics named after N. M. Emanuel, RAS
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Kosygina St., 4, 119334 Moscow, Russian Federation
Liliya Grigoryevna Damshkaln
Researcher,
Institute of Biochemical Physics named after N. M. Emanuel, RAS
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Kosygina St., 4, 119334 Moscow, Russian Federation
Mariam Grigoryevna Ezernitskaya
Candidate of Chemical Sciences, Senior Researcher,
A. N. Nesmeyanov Institute of Organoelement Compounds, RAS
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Vavilova St., 28, 119991 Moscow, Russian Federation
Yuliya Konstantinovna Glotova
Researcher,
Institute of Biochemical Physics named after N. M. Emanuel, RAS
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Kosygina St., 4, 119334 Moscow, Russian Federation
Abstract. Novel, previously unknown, wide pore poly(vinyl alcohol) cryogels (PVACGs) have been prepared through the cryotropic gelation approach, when water–PVA–gum Arabic (GuAr) ternary liquid systems were used as feeds. The following set of conditions necessary for obtaining wide-porous, permeable for a water flow, and, simultaneously, mechanically strong enough PVACGs was established: the total concentration of gelling component – PVA (MW of 86 kDa) and non-gelling polymer – GuAr (MW of ~650 kDa) should exceed ~14 wt. %, GuAr/PVA ratio should be near 1 : 1 (w/w), and the feed’s pH should be within the range of ~5-11. The phase diagrams for the water–PVA–GuAr ternary liquid systems at pH 5.3 and 10.0 have demonstrated that such “optimum” compositions are in the vicinity of the rectilinear diameters of the respective diagrams, and that the limit of GuAr solubility in the PVA-rich phase is small. In such cases this GuAr fraction strongly binds with PVA, especially under alkaline conditions, within the forming gel phase of heterophase PVACG. The light microscopy studies revealed the presence of at least three distinct kinds of pores in these cryogels. Firstly, there are interconnected channel-like gross pores with cross-section of 100-200 μm which are the replicas of continuous GuAr-rich phase in the two-phase polymeric systems appearing due to the liquid-liquid phase separation in the ternary water–PVA–GuAr system. The second type is represented by isolated roundish large pores ca. 10-70 μm in diameter being the replicas of GuAr-rich phase dispersed as liquid droplets in the PVA-rich phase. And the third type is represented by the smaller rounded pores ~1-5 μm in diameter being the replicas of ice polycrystals. Such sophisticated “poly-porous” morphology of the studied PVA cryogels is their unique feature distinguishing them from other known PVA cryogels.
Key words: poly(vinyl alcohol), gum Arabic, liquid-liquid phase separation, freezingthawing, wide pore cryogels.
Wide-Pore Cryogels Prepared Using the Combination of Liquid-Liquid Phase Separation and Cryotropic Gel-Formation Processes by Lozinskiy V.I., Antonov Yu.A., Damshkaln L.G., Ezernitskaya M.G., Glotova Yu.K. is licensed under a Creative Commons Attribution 4.0 International License.