Monolithic molecularly imprinted cryogel for lysozyme recognition

Rabieizadeh, Mohammadmahdi; Kashefimofrad, Seyed Mohammadreza

doi:10.1002/jssc.201400453

Cited by 23 publications

(19 citation statements)

References 31 publications

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“…[ 6 ] Nowadays cryogels have been developed to several formats including monolith, disc, membrane, and bead, which have found many applications in bioseparation, tissue engineering, heavy metal removal, and oil absorbent, among others. [7][8][9][10][11][12][13][14][15][16] Typically, cryogels possess supermacropores that lie normally in the range of several micrometers to several hundred micrometers in pore size, and are linked to form interconnected porous structure…”

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confidence: 99%

Synthesis of Hydrophobic Polymeric Cryogels with Supermacroporous Structure

Chen

Sui

Ren

et al. 2016

Macro Materials & Eng

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A versatile approach to synthesis of hydrophobic polymeric cryogels is proposed using acetic acid crystals instead of ice crystals as porogen through cryo‐polymerization. In the range of 60 to 90 vol% of acetic acid, polymerization at ambient temperature gives rise to particulate polymers in beaded or amorphous shape, while polymerization at 4 °C, lower than the melting point of acetic acid (16.6 °C), leads to the formation of cryogel‐like monoliths with supermacroporous structure, which is mainly ascribed to cryo‐concentration effect. According to the measurements by scanning electron microscopy and mercury intrusion porosimetry, the dried samples are supermacroporous with pore size mainly ranging from several micrometers to several hundred micrometers, which can be feasible for rapid mass transfer. The forming cryogels display a superfast responsiveness to organic solvents, possibly stemming from their supermacroporosity and distinctive hydrophobicity.

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confidence: 99%

Synthesis of Hydrophobic Polymeric Cryogels with Supermacroporous Structure

Chen

Sui

Ren

et al. 2016

Macro Materials & Eng

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“…However, the inherent drawbacks of cryogels are scarce functional monomers or crosslinkers with high activity and good water solubility for direct application or functionalization, difficulty in adjusting macropore structure, and the rather low specific surface area, which have been considered as the major challenges to broaden their applications [10]. Presently, most cryogels are used for purification of large biomolecules [11], such as DNA or dehydrogenase, chromatographic separation or capturing of proteins [12], tissue engineering [13], cell culturing [14], and so on. However, some cryogel composites have been exploited by traditional embedding of functional particles during cryogelation or immobilizing them on the pore surface of cryogels [15,16].…”

Section: Introductionmentioning

confidence: 99%

Organized cryogel composites with 3D hierarchical porosity as an extraction adsorbent for nucleosides

Zhao

Zou

Wang

et al. 2019

J of Separation Science

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Macroscopic monoliths are highly desirable in many fields of application. Herein, well organized organic–inorganic cryogel composite with a three‐dimensional hierarchical meso‐ and macroporous structure are presented, which were produced by in situ copolymerization of mesoporous multifunctional silica (size: 1–20 μm; pore: 2–20 nm mostly) and monomers (hydroxyethyl methacrylate and diallyldimethylammonium chloride) in water below the freezing point. This copolymerization method effectively adjusted the macropores of the basic cryogel, and the nanosilica was more homogeneously dispersed in the basic cryogel. The specific surface area of the cryogel composite was increased 17 times versus than that of the basic cryogel. The abundant meso‐ and macroporous pores on the cryogel composite provided sufficient reactive sites favorable for the efficient mass transport of target compounds. When the cryogel composite, as solid phase extraction adsorbent, was coupled with high‐performance liquid chromatography, an analytical tool, the nucleosides were quantified with good selectivity, lower detection limits (0.9–1.3 ng/mL) and satisfactory recoveries of greater than 80% from spiked human serum.

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“…Cryogelation was first established for the development of macroporous hydrophilic cryogels with interconnected macropores, and relatively higher mechanical strengths due to the structure of pore walls were formed as a result of the high polymer concentration in the nonfrozen liquid microphase . Recently, their potential for biotechnological applications has been explored, such as in our latest study on protein‐imprinted monolith polymer columns and technologically challenging separation processes, such as cell separation . However, current cryogelation processes cannot be used for the fabrication of nanosized particles because the dissolved solutes (monomers or polymer precursors) are squeezed by ice crystals to connect in the nonfrozen liquid microphase.…”

Section: Introductionmentioning

confidence: 99%

Poly(ether sulfone) nanoparticles and controllably modified nanoparticles obtained through temperature‐dependent cryogelation

Liu

Yang

et al. 2019

J of Applied Polymer Sci

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Poly(ether sulfone) (PES) nanoparticles (NPs) have broad application prospects in the field of nanomedicine. However, the current techniques could not be used to create PES-based NPs because of a lack of sophisticated equipment. In this study, a temperature-dependent cryogelation process was developed to fabricate PES NPs through PES self-assembly under unusually low polymer concentrations in the absence of any nanomanufacturing equipment or synthesis steps. The morphologies of the prepared NPs varied with the concentration difference of the initial PES solutions, and the diameter of the polymer particles reached about 50 nm with a high monodispersity. Furthermore, cocryogelation was explored in a novel manner to introduce two representative reversible addition −fragmentation chain-transfer (RAFT) agents onto the PES NPs separately for the following modification. Then, surface-initiated RAFT polymerization was also conducted to enable the controllable variation of the polymer brushes outside the NPs to verify their scalability for further application.

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Monolithic molecularly imprinted cryogel for lysozyme recognition

Cited by 23 publications

References 31 publications

Synthesis of Hydrophobic Polymeric Cryogels with Supermacroporous Structure

Synthesis of Hydrophobic Polymeric Cryogels with Supermacroporous Structure

Organized cryogel composites with 3D hierarchical porosity as an extraction adsorbent for nucleosides

Poly(ether sulfone) nanoparticles and controllably modified nanoparticles obtained through temperature‐dependent cryogelation

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