Your search keyword '"micelle morphology"' showing total 8 results

1. Calcium Silicate Hydrate Morphology Control and Its Effect on Cement Hydration.

Author

WEI Ting, ZHOU Shengjiang, DENG Zuiliang, LI Linhua, and YI Hongling

Subjects

CALCIUM silicate hydrate, DENTAL cements, CRITICAL micelle concentration, CEMENT, HEAT of hydration, PRECIPITATION (Chemistry)

Abstract

In the cement industry, the morphological control of calcium silicate hydrate (C-S-H) and its impact on cement hardening and hydration are important research topics. This study investigated the impact of template agents on C-S-H morphology and structure. By using chemical precipitation, amorphous, spherical, needle-like, and layered C-S-H with the template agents being sodium dodecyl benzene sulfonate (SDBS) and cetyl trimethyl ammonium bromide (CTAB) were prepared. An increase in SDBS concentration resulted in the transformation of the C-S-H morphology from disorderly to spherical, rod-shaped, and vesicular. When CTAB was used, an increased concentration resulted in the transformation of the C-S-H morphology from disorderly to spherical and layered. When the template agent concentration was greater than the critical micelle concentration (CMC), both the C-S-H crystallinity and CMC value decreased. The impact of different C-S-H morphologies on cement performance particularly cement hydration was also evaluated and analyzed. A significant correlation between cement hydration heat and strength was verified. Different microscopic C-S-H morphologies were used to design cement products, allowing the improvement of cement performance to varying degrees. Experimental results would provide an insight into the improvement of the performance of ordinary cement. [ABSTRACT FROM AUTHOR]

Published

2024

2. Morphology of the Micelles Formed by a Comb-Like PEG-Containing Copolymer Loaded with Antitumor Substances with Different Water Solubilities

Author

Mitina, N. Ye., Riabtseva, A. O., Garamus, V. M., Lesyk, R. B., Volyanyuk, K. A., Izhyk, O. M., and Zaichenko, O. S.

Subjects

комплекси полiмер/лiкарський препарат, hydrophobic/hydrophilic drugs, micelle morphology, small-angle X-ray scattering, polymer-drug complexes, technology, industry, and agriculture, морфологiя мiцел, малокутове рентгенiвське розсiювання, гiдрофобнi/гiдрофiльнi лiкарськi препарати

Abstract

The controlled delivery of anticancer drugs is driven by their interaction with carrier molecules. By creating complicated micelle-like complexes, amphiphilic polymers provide an opportunity to load drugs of various kinds. In this work, the interaction of the comb-like PEG-containing polymer poly(VEP-co-GMA)-graft-PEG with the water-soluble antitumor antibiotic doxorubicin and new water-insoluble derivatives of thiozalidinone Les-3883 characterized by a high anticancer efficiency has been studied in aqueous solutions by means of the SAXS, DLS, TEM, and photoluminescence methods. The formation of polymer micelles and their complexes with drugs, as well as their structural changes, is observed. The obtained results give evidence that the mechanism of organization of supramolecular complexes depends on the drug solubility in water. A potential capability of poly(VEP-co-GMA)-graft-PEG to prolong the drug circulation lifetime is confirmed., Контрольована доставка протипухлинних лiкiв базується на їх взаємодiї з молекулами-носiями. Амфiфiльнi полiмери, завдяки формуванню складних мiцелярних нанокомплексiв, дають змогу завантажити рiзноманiтнi лiки. Взаємодiя гребiнчастого ПЕГ-вмiсного полiмеру (полi(ВЕП-ко-ГМА)-графт-ПЕГ) з водорозчинним протипухлинним антибiотиком доксорубiцин i водонерозчинними новими похiдними тiозалiдiнону Les 3883 з високою протипухлинною дiєю дослiджувалась у водних розчинах за допомогою малокутового рентгенiвського розсiювання, динамiчного розсiювання свiтла, електронної мiкроскопiї та люмiнесценцiї. Було спостережено формування i структурнi змiни полiмерних мiцел та їх комплексiв з лiкарськими препаратами. Аналiз даних вказує на вiдмiнний характер в органiзацiї супрамолекулярних комплексiв в залежностi вiд водорозчинностi лiкарських препаратiв. Пiдтверджено потенцiйнi властивостi полi(ВЕП-ко-ГМА)-графт-ПЕГ для подовження циркуляцiї лiкiв.

Published

2020

3. Self-association dynamics and morphology of short polymeric PBA-b/co-PAA surfactants.

Author

Lamprou, Alexandros, Xie, Delong, Storti, Giuseppe, and Wu, Hua

Subjects

*SURFACE active agents, *STRUCTURAL dynamics, *BLOCK copolymers, *MICELLES, *ANALYTICAL mechanics, *COPOLYMERIZATION

Abstract

The self-association characteristics of very short and well-defined poly(butyl acrylate)-b-poly(acrylic acid) (PBA-b-PAA) block copolymers in water have been studied. The diblocks are asymmetric with the PBA block longer than the PAA block, giving rise to hollow sphere morphology. This is affirmed by experimental data and theoretical evaluations of the hydrophilic and hydrophobic domain sizes, as well as a value close to 1 for the ratio of the hydrodynamic to the gyration radius of the micelles. Besides, the untypically short PBA blocks (polymerization number around 15) render the micelles dynamic. Indications in support include among others the following: the CMC (critical micellar concentration) values depend, together with the aggregation numbers and the micellar sizes, on the block lengths, as predicted by theory; above the CMC their sizes are concentration-independent, while the micelles disappear below CMC. A comparison was also made with a random PBA- co-PAA copolymer of similar length, which self-associates at an apparent CMC 1 order of magnitude larger than those of the block copolymers, but the size of the formed micelles depends on the concentration. [ABSTRACT FROM AUTHOR]

Published

2014

4. Drug-Dependent Morphological Transitions in Spherical and Worm-Like Polymeric Micelles Define Stability and Pharmacological Performance of Micellar Drugs.

Author

Lim C, Ramsey JD, Hwang D, Teixeira SCM, Poon CD, Strauss JD, Rosen EP, Sokolsky-Papkov M, and Kabanov AV

Subjects

Drug Carriers chemistry, Nanomedicine, Polymers chemistry, Antineoplastic Agents therapeutic use, Micelles

Abstract

Significant advances in physicochemical properties of polymeric micelles enable optimization of therapeutic drug efficacy, supporting nanomedicine manufacturing and clinical translation. Yet, the effect of micelle morphology on pharmacological efficacy is not adequately addressed. This work addresses this gap by assessing pharmacological efficacy of polymeric micelles with spherical and worm-like morphologies. It is observed that poly(2-oxazoline)-based polymeric micelles can be elongated over time from a spherical structure to worm-like structure, with elongation influenced by several conditions, including the amount and type of drug loaded into the micelles. The role of different morphologies on pharmacological performance of drug loaded micelles against triple-negative breast cancer and pancreatic cancer tumor models is further evaluated. Spherical micelles accumulate rapidly in the tumor tissue while retaining large amounts of drug; worm-like micelles accumulate more slowly and only upon releasing significant amounts of drug. These findings suggest that the dynamic character of the drug-micelle structure and the micelle morphology play a critical role in pharmacological performance, and that spherical micelles are better suited for systemic delivery of anticancer drugs to tumors when drugs are loosely associated with the polymeric micelles., (© 2021 The Authors. Small published by Wiley-VCH GmbH.)

Published

2022

5. Physical and Biological Properties of Synthetic Polycations in Alginate Capsules

Author

Kleinberger, Rachelle, Stover, Harald, and Chemistry

Subjects

Micelle morphology, Polyelectrolyte Complexation, Thermo-responsive polymers, RAFT polymerization, Covalent cross-linking, Cell Encapsulation, Polycations, Polymer chemistry, mechanical properties, Micropipette Aspiration, Block copolymers, Alginate beads

Abstract

The use of cell transplantation to treat enzyme deficiency disorders is limited by the immune response targeted against foreign tissue or the use of life-long immunosuppressants. Hiding cells from the immune system in an encapsulation device is promising. Cells encapsulated within an anionic calcium alginate hydrogel bead are protected through a semi-permeable membrane formed by polycation, poly-L-lysine (PLL). A final layer of alginate is added to hide the cationic PLL surface but this has proved to be difficult creating capsules which are prone to fibrotic overgrowth, blocking exchange of nutrients, waste and therapeutic enzymes through the capsule. For long term applications these capsules need to be both biocompatible and mechanically robust. This thesis aims to address the biocompatibility issue of high cationic surface charge by synthesizing polycations of reduced charge using N-(3- aminopropyl)methacrylamide hydrochloride (APM) and N-(2- hydroxypropyl)methacrylamide (HPM) and study the associated mechanical properties of the capsules using micropipette aspiration. Micropipette aspiration was applied and validated for alginate based capsules (gel and liquid core) to quantify stiffness. Varying ratios of APM were used to control the overall charge of the polycations formed while HPM was incorporated as a neutral, hydrophilic, nonfouling comonomer. The molecular weight (MW) was controlled by using reversible addition-fragmentation chain transfer (RAFT) polymerization. The biocompatibility of these polymers was tested by cell adhesion and proliferation of 3T3 fibroblasts onto APM/HPM copolymer functionalized surfaces and by solution toxicity against C2C12 myoblasts. The ability for the APM/HPM copolymers to bind to alginate and form capsules was also assessed, along with the integrity and stiffness of the capsule membrane with or without additional covalent cross-linking by reactive polyanion, poly(methacrylic acid-co-2-vinyl-4,4- dimethylazlactone) (PMV60). Thermo-responsive block copolymers of N-isopropylacrylamide (NIPAM) and 2- hydroxyethylacrylamide (HEA) were also synthesized as potential drug delivery nanoparticles, showing control over micelle morphology with varying NIPAM to HEA ratios. Thesis Doctor of Science (PhD) The treatment of enzyme deficiency disorders by cell transplantation is limited by the immune attack of foreign tissue in absence of immunosuppressants. Cells protected in an encapsulation device has shown promise. Poly-L-lysine, a widely used membrane material in these protective capsules, binds to the anionic gel entrapping living cells because it is highly cationic. The high cationic charge is difficult to hide causing the immune system to build tissue around the capsule, preventing the encapsulated cells from exchanging nutrients and therapeutic enzymes. This thesis aims to replace poly-L-lysine by synthesizing a series of more biocompatible materials of decreasing cationic charge. These materials were studied for the ability to support tissue growth and form stable capsules. The membrane strength was measured using an aspiration method validated for these types of capsules. Reducing the cationic charge of the materials increased the biocompatibility of the capsule membrane but also made for weaker membranes.

Published

2017

6. Self-association dynamics and morphology of short polymeric PBA-b/co-PAA surfactants

Author

Giuseppe Storti, Alexandros Lamprou, Delong Xie, and Hua Wu

Subjects

Morphology (linguistics), Materials science, Polymers and Plastics, PBA-b-PAA, Block copolymer, Butyl acrylate, ATRP, Micelle, Gyration, chemistry.chemical_compound, Colloid and Surface Chemistry, Polymer chemistry, Materials Chemistry, Copolymer, Micellemorphology, Physical and Theoretical Chemistry, Acrylic acid, Micelle morphology, Vesicle, Self-assembly dynamics, Polymeric surfactants, chemistry, Chemical engineering, Polymerization, Critical micelle concentration

Abstract

The self-association characteristics of very short and well-defined poly(butyl acrylate)-b-poly(acrylic acid) (PBA-b-PAA) block copolymers in water have been studied. The diblocks are asymmetric with the PBA block longer than the PAA block, giving rise to hollow sphere morphology. This is affirmed by experimental data and theoretical evaluations of the hydrophilic and hydrophobic domain sizes, as well as a value close to 1 for the ratio of the hydrodynamic to the gyration radius of the micelles. Besides, the untypically short PBA blocks (polymerization number around 15) render the micelles dynamic. Indications in support include among others the following: the CMC (critical micellar concentration) values depend, together with the aggregation numbers and the micellar sizes, on the block lengths, as predicted by theory; above the CMC their sizes are concentration-independent, while the micelles disappear below CMC. A comparison was also made with a random PBA-co-PAA copolymer of similar length, which self-associates at an apparent CMC 1 order of magnitude larger than those of the block copolymers, but the size of the formed micelles depends on the concentration., Colloid & polymer science, 292 (3), ISSN:0303-402X, ISSN:1435-1536

Published

2014

7. Structure of PEP-PEO block copolymer micelles: Exploiting the complementarity of small-angle X-ray scattering and static light scattering

Author

Jan Skov Pedersen, Qing Shi, Grethe Vestergaard Jensen, Kristoffer Almdal, Cristiano L. P. Oliveira, María J. Hernansanz, and G. Roshan Deen

Subjects

Morphology, Materials science, micelles, Micelle structure, X ray scattering, Analytical chemistry, PEO molecular weight, Neutron scattering, static light scattering, Micelle, General Biochemistry, Genetics and Molecular Biology, Light scattering, Ethylene, Contrast variation, Copolymerization, Two-component, Block copolymer micelles, Static light scattering, Internal structure, Scattering vectors, chemistry.chemical_classification, Micelle morphology, Core-shell model, Ethanol solutions, Polyethylene oxides, Ethanol, X rays, Scattering, Small-angle X-ray scattering, Spherical micelles, Polymer, Small-angle neutron scattering, Block copolymers, Ethylene oxides, Crystallography, Refraction, chemistry, small-angle X-ray scattering, Length scale, Propylene

Abstract

The structure of large block copolymer micelles is traditionally determined by small-angle neutron scattering (SANS), covering a large range of scattering vectors and employing contrast variation to determine the overall micelle morphology as well as the internal structure on shorter length scales. The present work shows that the same information can be obtained by combining static light scattering (SLS) and small-angle X-ray scattering (SAXS), which provide information on, respectively, large and short length scales. Micelles of a series of block copolymers of poly(ethylene propylene)-b-poly(ethylene oxide) (PEP–PEO) in a 70% ethanol solution are investigated. The polymers have identical PEP blocks of 5.0 kDa and varying PEO blocks of 2.8–49 kDa. The SLS contrasts of PEP and PEO are similar, providing a homogeneous contrast, making SLS ideal for determining the overall micelle morphology. The SAXS contrasts of the two components are very different, allowing for resolution of the internal micelle structure. A core–shell model with a PEP core and PEO corona is fitted simultaneously to the SAXS and SLS data using the different contrasts of the two blocks for each technique. With increasing PEO molecular weight, a transition from cylindrical to spherical micelles is observed. This transition cannot be identified from the SAXS data alone, but only from the SLS data.

Published

2011

8. Structure of PEP-PEO block copolymer micelles: Exploiting the complementarity of small-angle X-ray scattering and static light scattering

Author

Jensen, Grethe Vestergaard, Shi, Qing, Hernansanz, María J., Oliveira, Cristiano L. P., Deen, G. Roshan, Almdal, Kristoffer, Pedersen, Jan Skov, Jensen, Grethe Vestergaard, Shi, Qing, Hernansanz, María J., Oliveira, Cristiano L. P., Deen, G. Roshan, Almdal, Kristoffer, and Pedersen, Jan Skov

Abstract

The structure of large block copolymer micelles is traditionally determined by small-angle neutron scattering (SANS), covering a large range of scattering vectors and employing contrast variation to determine the overall micelle morphology as well as the internal structure on shorter length scales. The present work shows that the same information can be obtained by combining static light scattering (SLS) and small-angle X-ray scattering (SAXS), which provide information on, respectively, large and short length scales. Micelles of a series of block copolymers of poly(ethylene propylene)-b-poly(ethylene oxide) (PEP-PEO) in a 70% ethanol solution are investigated. The polymers have identical PEP blocks of 5.0 kDa and varying PEO blocks of 2.8-49 kDa. The SLS contrasts of PEP and PEO are similar, providing a homogeneous contrast, making SLS ideal for determining the overall micelle morphology. The SAXS contrasts of the two components are very different, allowing for resolution of the internal micelle structure. A core-shell model with a PEP core and PEO corona is fitted simultaneously to the SAXS and SLS data using the different contrasts of the two blocks for each technique. With increasing PEO molecular weight, a transition from cylindrical to spherical micelles is observed. This transition cannot be identified from the SAXS data alone, but only from the SLS data.

Published

2011