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Micelle

February 27, 2023

A micelle (/mˈsɛl/) or micella (/mˈsɛlə/) (plural micelles or micellae, respectively) is an aggregate (or supramolecular assembly) of surfactant amphipathic lipid molecules dispersed in a liquid, forming a colloidal suspension (also known as associated colloidal system[4]). A typical micelle in water forms an aggregate with the hydrophilic "head" regions in contact with surrounding solvent, sequestering the hydrophobic single-tail regions in the micelle centre.

Micelle
IUPAC definition
MicelleParticle of colloidal dimensions that exists in equilibrium with the molecules or ions in solution from which it is formed.[1][2]
Micelle (polymers)Organized auto-assembly formed in a liquid and composed of amphiphilic macromolecules, in general amphiphilic di- or tri-block copolymers made of solvophilic and solvophobic blocks.
Note 1An amphiphilic behavior can be observed for water and an organic solvent or between two organic solvents.
Note 2Polymeric micelles have a much lower critical micellar concentration (CMC) than soap (0.0001 to 0.001 mol/L) or surfactant micelles, but are nevertheless at equilibrium with isolated macromolecules called unimers. Therefore, micelle formation and stability are concentration-dependent.[3]
Cross-section view of the structures that can be formed by phospholipids in aqueous solutions (unlike this illustration, micelles are usually formed by single-chain lipids, since it is difficult to fit two chains into this shape)
Scheme of a micelle formed by phospholipids in an aqueous solution

This phase is caused by the packing behavior of single-tail lipids in a bilayer. The difficulty filling all the volume of the interior of a bilayer, while accommodating the area per head group forced on the molecule by the hydration of the lipid head group, leads to the formation of the micelle. This type of micelle is known as a normal-phase micelle (oil-in-water micelle). Inverse micelles have the head groups at the centre with the tails extending out (water-in-oil micelle).

Micelles are approximately spherical in shape. Other phases, including shapes such as ellipsoids, cylinders, and bilayers, are also possible. The shape and size of a micelle are a function of the molecular geometry of its surfactant molecules and solution conditions such as surfactant concentration, temperature, pH, and ionic strength. The process of forming micelles is known as micellisation and forms part of the phase behaviour of many lipids according to their polymorphism.[5]

History

The ability of a soapy solution to act as a detergent has been recognized for centuries. However, it was only at the beginning of the twentieth century that the constitution of such solutions was scientifically studied. Pioneering work in this area was carried out by James William McBain at the University of Bristol. As early as 1913, he postulated the existence of "colloidal ions" to explain the good electrolytic conductivity of sodium palmitate solutions.[6] These highly mobile, spontaneously formed clusters came to be called micelles, a term borrowed from biology and popularized by G.S. Hartley in his classic book Paraffin Chain Salts: A Study in Micelle Formation.[7] The term micelle was coined in nineteenth century scientific literature as the ‑elle diminutive of the Latin word mica (particle), conveying a new word for "tiny particle".[8]

Solvation

Individual surfactant molecules that are in the system but are not part of a micelle are called "monomers". Micelles represent a molecular assembly, in which the individual components are thermodynamically in equilibrium with monomers of the same species in the surrounding medium. In water, the hydrophilic "heads" of surfactant molecules are always in contact with the solvent, regardless of whether the surfactants exist as monomers or as part of a micelle. However, the lipophilic "tails" of surfactant molecules have less contact with water when they are part of a micelle—this being the basis for the energetic drive for micelle formation. In a micelle, the hydrophobic tails of several surfactant molecules assemble into an oil-like core, the most stable form of which having no contact with water. By contrast, surfactant monomers are surrounded by water molecules that create a "cage" or solvation shell connected by hydrogen bonds. This water cage is similar to a clathrate and has an ice-like crystal structure and can be characterized according to the hydrophobic effect. The extent of lipid solubility is determined by the unfavorable entropy contribution due to the ordering of the water structure according to the hydrophobic effect.

Micelles composed of ionic surfactants have an electrostatic attraction to the ions that surround them in solution, the latter known as counterions. Although the closest counterions partially mask a charged micelle (by up to 92%), the effects of micelle charge affect the structure of the surrounding solvent at appreciable distances from the micelle. Ionic micelles influence many properties of the mixture, including its electrical conductivity. Adding salts to a colloid containing micelles can decrease the strength of electrostatic interactions and lead to the formation of larger ionic micelles.[9] This is more accurately seen from the point of view of an effective charge in hydration of the system.

Energy of formation

See also: Thermodynamics of micellization

Micelles form only when the concentration of surfactant is greater than the critical micelle concentration (CMC), and the temperature of the system is greater than the critical micelle temperature, or Krafft temperature. The formation of micelles can be understood using thermodynamics: Micelles can form spontaneously because of a balance between entropy and enthalpy. In water, the hydrophobic effect is the driving force for micelle formation, despite the fact that assembling surfactant molecules is unfavorable in terms of both enthalpy and entropy of the system. At very low concentrations of the surfactant, only monomers are present in solution. As the concentration of the surfactant is increased, a point is reached at which the unfavorable entropy contribution, from clustering the hydrophobic tails of the molecules, is overcome by a gain in entropy due to release of the solvation shells around the surfactant tails. At this point, the lipid tails of a part of the surfactants must be segregated from the water. Hence, they start to form micelles. In broad terms, above the CMC, the loss of entropy due to assembly of the surfactant molecules is less than the gain in entropy by setting free the water molecules that were "trapped" in the solvation shells of the surfactant monomers. Also important are enthalpic considerations, such as the electrostatic interactions that occur between the charged parts of surfactants.

Micelle packing parameter

The micelle packing parameter equation is utilized to help "predict molecular self-assembly in surfactant solutions":[10]

 

where   is the surfactant tail volume,   is the tail length, and   is the equilibrium area per molecule at the aggregate surface.

Block copolymer micelles

The concept of micelles was introduced to describe the core-corona aggregates of small surfactant molecules, however it has also extended to describe aggregates of amphiphilic block copolymers in selective solvents.[11][12] It is important to know the difference between these two systems. The major difference between these two types of aggregates is in the size of their building blocks. Surfactant molecules have a molecular weight which is generally of a few hundreds of grams per mole while block copolymers are generally one or two orders of magnitude larger. Moreover, thanks to the larger hydrophilic and hydrophobic parts, block copolymers can have a much more pronounced amphiphilic nature when compared to surfactant molecules.

Because of these differences in the building blocks, some block copolymer micelles behave like surfactant ones, while others don't. It is necessary therefore to make a distinction between the two situations. The former ones will belong to the dynamic micelles while the latter will be called kinetically frozen micelles.

Dynamic micelles

Certain amphiphilic block copolymer micelles display a similar behavior as surfactant micelles. These are generally called dynamic micelles and are characterized by the same relaxation processes assigned to surfactant exchange and micelle scission/recombination. Although the relaxation processes are the same between the two types of micelles, the kinetics of unimer exchange are very different. While in surfactant systems the unimers leave and join the micelles through a diffusion-controlled process, for copolymers the entry rate constant is slower than a diffusion controlled process. The rate of this process was found to be a decreasing power-law of the degree of polymerization of the hydrophobic block to the power 2/3. This difference is due to the coiling of the hydrophobic block of a copolymer exiting the core of a micelle.[13]

Block copolymers which form dynamic micelles are some of the tri-block Poloxamers under the right conditions.

Kinetically frozen micelles

When block copolymer micelles don't display the characteristic relaxation processes of surfactant micelles, these are called kinetically frozen micelles. These can be achieved in two ways: when the unimers forming the micelles are not soluble in the solvent of the micelle solution, or if the core forming blocks are glassy at the temperature in which the micelles are found. Kinetically frozen micelles are formed when either of these conditions is met. A special example in which both of these conditions are valid is that of polystyrene-b-poly(ethylene oxide). This block copolymer is characterized by the high hydrophobicity of the core forming block, PS, which causes the unimers to be insoluble in water. Moreover, PS has a high glass transition temperature which is, depending on the molecular weight, higher than room temperature. Thanks to these two characteristics, a water solution of PS-PEO micelles of sufficiently high molecular weight can be considered kinetically frozen. This means that none of the relaxation processes, which would drive the micelle solution towards thermodynamic equilibrium, are possible.[14] Pioneering work on these micelles was done by Adi Eisenberg.[15] It was also shown how the lack of relaxation processes allowed great freedom in the possible morphologies formed.[16][17] Moreover, the stability against dilution and vast range of morphologies of kinetically frozen micelles make them particularly interesting, for example, for the development of long circulating drug delivery nanoparticles.[18]

Inverse/reverse micelles

In a non-polar solvent, it is the exposure of the hydrophilic head groups to the surrounding solvent that is energetically unfavourable, giving rise to a water-in-oil system. In this case, the hydrophilic groups are sequestered in the micelle core and the hydrophobic groups extend away from the center. These inverse micelles are proportionally less likely to form on increasing headgroup charge, since hydrophilic sequestration would create highly unfavorable electrostatic interactions.

It is well established that for many surfactant/solvent systems a small fraction of the inverse micelles spontaneously acquire a net charge of +qe or -qe. This charging takes place through a disproportionation/comproportionation mechanism rather than a dissociation/association mechanism and the equilibrium constant for this reaction is on the order of 10−4 to 10−11, which means about every 1 in 100 to 1 in 100 000 micelles will be charged.[19]

Supermicelles

 
Electron micrograph of the windmill-like supermicelle, scale bar 500 nm.[20]

Supermicelle is a hierarchical micelle structure (supramolecular assembly) where individual components are also micelles. Supermicelles are formed via bottom-up chemical approaches, such as self-assembly of long cylindrical micelles into radial cross-, star- or dandelion-like patterns in a specially selected solvent; solid nanoparticles may be added to the solution to act as nucleation centers and form the central core of the supermicelle. The stems of the primary cylindrical micelles are composed of various block copolymers connected by strong covalent bonds; within the supermicelle structure they are loosely held together by hydrogen bonds, electrostatic or solvophobic interactions.[20][21]

Uses

Action of soap on oil

When surfactants are present above the critical micelle concentration (CMC), they can act as emulsifiers that will allow a compound that is normally insoluble (in the solvent being used) to dissolve. This occurs because the insoluble species can be incorporated into the micelle core, which is itself solubilized in the bulk solvent by virtue of the head groups' favorable interactions with solvent species. The most common example of this phenomenon is detergents, which clean poorly soluble lipophilic material (such as oils and waxes) that cannot be removed by water alone. Detergents clean also by lowering the surface tension of water, making it easier to remove material from a surface. The emulsifying property of surfactants is also the basis for emulsion polymerization.

Micelles may also have important roles in chemical reactions. Micellar chemistry uses the interior of micelles to harbor chemical reactions, which in some cases can make multi-step chemical synthesis more feasible.[22][23] Doing so can increase reaction yield, create conditions more favorable to specific reaction products (e.g. hydrophobic molecules), and reduce required solvents, side products, and required conditions (e.g. extreme pH). Because of these benefits, Micellular chemistry is thus considered a form of Green chemistry.[24] However, micelle formation may also inhibit chemical reactions, such as when reacting molecules form micelles that shield a molecular component vulnerable to oxidation.[25]

Micelle formation is essential for the absorption of fat-soluble vitamins and complicated lipids within the human body. Bile salts formed in the liver and secreted by the gall bladder allow micelles of fatty acids to form. This allows the absorption of complicated lipids (e.g., lecithin) and lipid-soluble vitamins (A, D, E, and K) within the micelle by the small intestine.

During the process of milk-clotting, proteases act on the soluble portion of caseins, κ-casein, thus originating an unstable micellar state that results in clot formation.

Micelles can also be used for targeted drug delivery as gold nanoparticles.[26]

See also

References

 
Scholia has a topic profile for Micelle.
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February 27, 2023
micelle, micelle, micella, plural, micelles, micellae, respectively, aggregate, supramolecular, assembly, surfactant, amphipathic, lipid, molecules, dispersed, liquid, forming, colloidal, suspension, also, known, associated, colloidal, system, typical, micelle. A micelle m aɪ ˈ s ɛ l or micella m aɪ ˈ s ɛ l e plural micelles or micellae respectively is an aggregate or supramolecular assembly of surfactant amphipathic lipid molecules dispersed in a liquid forming a colloidal suspension also known as associated colloidal system 4 A typical micelle in water forms an aggregate with the hydrophilic head regions in contact with surrounding solvent sequestering the hydrophobic single tail regions in the micelle centre MicelleIUPAC definitionMicelleParticle of colloidal dimensions that exists in equilibrium with the molecules or ions in solution from which it is formed 1 2 Micelle polymers Organized auto assembly formed in a liquid and composed of amphiphilic macromolecules in general amphiphilic di or tri block copolymers made of solvophilic and solvophobic blocks Note 1An amphiphilic behavior can be observed for water and an organic solvent or between two organic solvents Note 2Polymeric micelles have a much lower critical micellar concentration CMC than soap 0 0001 to 0 001 mol L or surfactant micelles but are nevertheless at equilibrium with isolated macromolecules called unimers Therefore micelle formation and stability are concentration dependent 3 Cross section view of the structures that can be formed by phospholipids in aqueous solutions unlike this illustration micelles are usually formed by single chain lipids since it is difficult to fit two chains into this shape Scheme of a micelle formed by phospholipids in an aqueous solution This phase is caused by the packing behavior of single tail lipids in a bilayer The difficulty filling all the volume of the interior of a bilayer while accommodating the area per head group forced on the molecule by the hydration of the lipid head group leads to the formation of the micelle This type of micelle is known as a normal phase micelle oil in water micelle Inverse micelles have the head groups at the centre with the tails extending out water in oil micelle Micelles are approximately spherical in shape Other phases including shapes such as ellipsoids cylinders and bilayers are also possible The shape and size of a micelle are a function of the molecular geometry of its surfactant molecules and solution conditions such as surfactant concentration temperature pH and ionic strength The process of forming micelles is known as micellisation and forms part of the phase behaviour of many lipids according to their polymorphism 5 Contents 1 History 2 Solvation 3 Energy of formation 4 Micelle packing parameter 5 Block copolymer micelles 5 1 Dynamic micelles 5 2 Kinetically frozen micelles 6 Inverse reverse micelles 7 Supermicelles 8 Uses 9 See also 10 ReferencesHistory EditThe ability of a soapy solution to act as a detergent has been recognized for centuries However it was only at the beginning of the twentieth century that the constitution of such solutions was scientifically studied Pioneering work in this area was carried out by James William McBain at the University of Bristol As early as 1913 he postulated the existence of colloidal ions to explain the good electrolytic conductivity of sodium palmitate solutions 6 These highly mobile spontaneously formed clusters came to be called micelles a term borrowed from biology and popularized by G S Hartley in his classic book Paraffin Chain Salts A Study in Micelle Formation 7 The term micelle was coined in nineteenth century scientific literature as the elle diminutive of the Latin word mica particle conveying a new word for tiny particle 8 Solvation EditIndividual surfactant molecules that are in the system but are not part of a micelle are called monomers Micelles represent a molecular assembly in which the individual components are thermodynamically in equilibrium with monomers of the same species in the surrounding medium In water the hydrophilic heads of surfactant molecules are always in contact with the solvent regardless of whether the surfactants exist as monomers or as part of a micelle However the lipophilic tails of surfactant molecules have less contact with water when they are part of a micelle this being the basis for the energetic drive for micelle formation In a micelle the hydrophobic tails of several surfactant molecules assemble into an oil like core the most stable form of which having no contact with water By contrast surfactant monomers are surrounded by water molecules that create a cage or solvation shell connected by hydrogen bonds This water cage is similar to a clathrate and has an ice like crystal structure and can be characterized according to the hydrophobic effect The extent of lipid solubility is determined by the unfavorable entropy contribution due to the ordering of the water structure according to the hydrophobic effect Micelles composed of ionic surfactants have an electrostatic attraction to the ions that surround them in solution the latter known as counterions Although the closest counterions partially mask a charged micelle by up to 92 the effects of micelle charge affect the structure of the surrounding solvent at appreciable distances from the micelle Ionic micelles influence many properties of the mixture including its electrical conductivity Adding salts to a colloid containing micelles can decrease the strength of electrostatic interactions and lead to the formation of larger ionic micelles 9 This is more accurately seen from the point of view of an effective charge in hydration of the system Energy of formation EditSee also Thermodynamics of micellization Micelles form only when the concentration of surfactant is greater than the critical micelle concentration CMC and the temperature of the system is greater than the critical micelle temperature or Krafft temperature The formation of micelles can be understood using thermodynamics Micelles can form spontaneously because of a balance between entropy and enthalpy In water the hydrophobic effect is the driving force for micelle formation despite the fact that assembling surfactant molecules is unfavorable in terms of both enthalpy and entropy of the system At very low concentrations of the surfactant only monomers are present in solution As the concentration of the surfactant is increased a point is reached at which the unfavorable entropy contribution from clustering the hydrophobic tails of the molecules is overcome by a gain in entropy due to release of the solvation shells around the surfactant tails At this point the lipid tails of a part of the surfactants must be segregated from the water Hence they start to form micelles In broad terms above the CMC the loss of entropy due to assembly of the surfactant molecules is less than the gain in entropy by setting free the water molecules that were trapped in the solvation shells of the surfactant monomers Also important are enthalpic considerations such as the electrostatic interactions that occur between the charged parts of surfactants Micelle packing parameter EditThe micelle packing parameter equation is utilized to help predict molecular self assembly in surfactant solutions 10 v o a e ℓ o displaystyle frac v o a e ell o where v o displaystyle v o is the surfactant tail volume ℓ o displaystyle ell o is the tail length and a e displaystyle a e is the equilibrium area per molecule at the aggregate surface Block copolymer micelles EditThe concept of micelles was introduced to describe the core corona aggregates of small surfactant molecules however it has also extended to describe aggregates of amphiphilic block copolymers in selective solvents 11 12 It is important to know the difference between these two systems The major difference between these two types of aggregates is in the size of their building blocks Surfactant molecules have a molecular weight which is generally of a few hundreds of grams per mole while block copolymers are generally one or two orders of magnitude larger Moreover thanks to the larger hydrophilic and hydrophobic parts block copolymers can have a much more pronounced amphiphilic nature when compared to surfactant molecules Because of these differences in the building blocks some block copolymer micelles behave like surfactant ones while others don t It is necessary therefore to make a distinction between the two situations The former ones will belong to the dynamic micelles while the latter will be called kinetically frozen micelles Dynamic micelles Edit Certain amphiphilic block copolymer micelles display a similar behavior as surfactant micelles These are generally called dynamic micelles and are characterized by the same relaxation processes assigned to surfactant exchange and micelle scission recombination Although the relaxation processes are the same between the two types of micelles the kinetics of unimer exchange are very different While in surfactant systems the unimers leave and join the micelles through a diffusion controlled process for copolymers the entry rate constant is slower than a diffusion controlled process The rate of this process was found to be a decreasing power law of the degree of polymerization of the hydrophobic block to the power 2 3 This difference is due to the coiling of the hydrophobic block of a copolymer exiting the core of a micelle 13 Block copolymers which form dynamic micelles are some of the tri block Poloxamers under the right conditions Kinetically frozen micelles Edit When block copolymer micelles don t display the characteristic relaxation processes of surfactant micelles these are called kinetically frozen micelles These can be achieved in two ways when the unimers forming the micelles are not soluble in the solvent of the micelle solution or if the core forming blocks are glassy at the temperature in which the micelles are found Kinetically frozen micelles are formed when either of these conditions is met A special example in which both of these conditions are valid is that of polystyrene b poly ethylene oxide This block copolymer is characterized by the high hydrophobicity of the core forming block PS which causes the unimers to be insoluble in water Moreover PS has a high glass transition temperature which is depending on the molecular weight higher than room temperature Thanks to these two characteristics a water solution of PS PEO micelles of sufficiently high molecular weight can be considered kinetically frozen This means that none of the relaxation processes which would drive the micelle solution towards thermodynamic equilibrium are possible 14 Pioneering work on these micelles was done by Adi Eisenberg 15 It was also shown how the lack of relaxation processes allowed great freedom in the possible morphologies formed 16 17 Moreover the stability against dilution and vast range of morphologies of kinetically frozen micelles make them particularly interesting for example for the development of long circulating drug delivery nanoparticles 18 Inverse reverse micelles EditIn a non polar solvent it is the exposure of the hydrophilic head groups to the surrounding solvent that is energetically unfavourable giving rise to a water in oil system In this case the hydrophilic groups are sequestered in the micelle core and the hydrophobic groups extend away from the center These inverse micelles are proportionally less likely to form on increasing headgroup charge since hydrophilic sequestration would create highly unfavorable electrostatic interactions It is well established that for many surfactant solvent systems a small fraction of the inverse micelles spontaneously acquire a net charge of qe or qe This charging takes place through a disproportionation comproportionation mechanism rather than a dissociation association mechanism and the equilibrium constant for this reaction is on the order of 10 4 to 10 11 which means about every 1 in 100 to 1 in 100 000 micelles will be charged 19 Supermicelles Edit Electron micrograph of the windmill like supermicelle scale bar 500 nm 20 Supermicelle is a hierarchical micelle structure supramolecular assembly where individual components are also micelles Supermicelles are formed via bottom up chemical approaches such as self assembly of long cylindrical micelles into radial cross star or dandelion like patterns in a specially selected solvent solid nanoparticles may be added to the solution to act as nucleation centers and form the central core of the supermicelle The stems of the primary cylindrical micelles are composed of various block copolymers connected by strong covalent bonds within the supermicelle structure they are loosely held together by hydrogen bonds electrostatic or solvophobic interactions 20 21 Uses Edit source source source source source source source source source source source source source source track track Action of soap on oil When surfactants are present above the critical micelle concentration CMC they can act as emulsifiers that will allow a compound that is normally insoluble in the solvent being used to dissolve This occurs because the insoluble species can be incorporated into the micelle core which is itself solubilized in the bulk solvent by virtue of the head groups favorable interactions with solvent species The most common example of this phenomenon is detergents which clean poorly soluble lipophilic material such as oils and waxes that cannot be removed by water alone Detergents clean also by lowering the surface tension of water making it easier to remove material from a surface The emulsifying property of surfactants is also the basis for emulsion polymerization Micelles may also have important roles in chemical reactions Micellar chemistry uses the interior of micelles to harbor chemical reactions which in some cases can make multi step chemical synthesis more feasible 22 23 Doing so can increase reaction yield create conditions more favorable to specific reaction products e g hydrophobic molecules and reduce required solvents side products and required conditions e g extreme pH Because of these benefits Micellular chemistry is thus considered a form of Green chemistry 24 However micelle formation may also inhibit chemical reactions such as when reacting molecules form micelles that shield a molecular component vulnerable to oxidation 25 Micelle formation is essential for the absorption of fat soluble vitamins and complicated lipids within the human body Bile salts formed in the liver and secreted by the gall bladder allow micelles of fatty acids to form This allows the absorption of complicated lipids e g lecithin and lipid soluble vitamins A D E and K within the micelle by the small intestine During the process of milk clotting proteases act on the soluble portion of caseins k casein thus originating an unstable micellar state that results in clot formation Micelles can also be used for targeted drug delivery as gold nanoparticles 26 See also EditCritical micelle concentration Micellar liquid chromatography Micellar solutions Micellar solubilization Lipid bilayer Liposome Surfactant Vesicle biology AmphiphileReferences Edit Scholia has a topic profile for Micelle MacNaugdoesht Alan D Wilkinson Andrew R eds 1997 Compendium of Chemical Terminology IUPAC Recommendations 2nd ed Oxford Blackwell Science ISBN 978 0865426849 Slomkowski Stanislaw Aleman Jose V Gilbert Robert G Hess Michael Horie Kazuyuki Jones himanshu G Kubisa Przemyslaw Meisel Ingrid Mormann Werner Penczek Stanislaw Stepto Robert F T 2011 Terminology of polymers and polymerization processes in dispersed systems IUPAC Recommendations 2011 Pure and Applied Chemistry 83 12 2229 2259 doi 10 1351 PAC REC 10 06 03 Vert Michel Doi Yoshiharu Hellwich Karl Heinz Hess Michael Hodge Philip Kubisa Przemyslaw Rinaudo Marguerite Schue Francois 2012 Terminology for biorelated polymers and applications IUPAC Recommendations 2012 Pure and Applied Chemistry 84 2 377 410 doi 10 1351 PAC REC 10 12 04 Doubtnut What are Associated Colloids Given an example doubtnut Retrieved 2021 02 26 I W Hamley Introduction to Soft Matter John Wiley 2007 McBain J W Trans Faraday Soc 1913 9 99 Hartley G S 1936 Aqueous Solutions of Paraffin Chain Salts A Study in Micelle Formation Hermann et Cie Paris Micelle Merriam Webster Dictionary Retrieved September 29 2018 Turro Nicholas J Yekta Ahmad 1978 Luminescent probes for detergent solutions A simple procedure for determination of the mean aggregation number of micelles Journal of the American Chemical Society 100 18 5951 5952 doi 10 1021 ja00486a062 Nagarajan R 2002 Molecular Packing Parameter and Surfactant Self Assembly The Neglected Role of the Surfactant Tail Langmuir 18 31 38 doi 10 1021 la010831y Hamley I W Block Copolymers in Solution Wiley 2005 Kocak G Tuncer C Butun V 2016 12 20 pH Responsive polymers Polym Chem 8 1 144 176 doi 10 1039 c6py01872f ISSN 1759 9962 Zana Raoul Marques Carlos Johner Albert 2006 11 16 Dynamics of micelles of the triblock copolymers poly ethylene oxide poly propylene oxide poly ethylene oxide in aqueous solution Advances in Colloid and Interface Science Special Issue in Honor of Dr K L Mittal 123 126 345 351 doi 10 1016 j cis 2006 05 011 PMID 16854361 Nicolai Taco Colombani Olivier Chassenieux Christophe 2010 Dynamic polymeric micelles versus frozen nanoparticles formed by block copolymers Soft Matter 6 14 3111 Bibcode 2010SMat 6 3111N doi 10 1039 b925666k Prescott R J 1983 Communications to the editor Journal of Psychosomatic Research 27 4 327 329 doi 10 1016 0022 3999 83 90056 9 PMID 6620210 Zhang L Eisenberg A 1995 Multiple Morphologies of Crew Cut Aggregates of Polystyrene b poly acrylic acid Block Copolymers Science 268 5218 1728 31 Bibcode 1995Sci 268 1728Z doi 10 1126 science 268 5218 1728 PMID 17834990 S2CID 5854900 Zhu Jintao Hayward Ryan C 2008 06 01 Spontaneous Generation of Amphiphilic Block Copolymer Micelles with Multiple Morphologies through Interfacial Instabilities Journal of the American Chemical Society 130 23 7496 7502 doi 10 1021 ja801268e PMID 18479130 D Addio Suzanne M Saad Walid Ansell Steven M Squiers John J Adamson Douglas H Herrera Alonso Margarita Wohl Adam R Hoye Thomas R Macosko Christopher W 2012 08 20 Effects of block copolymer properties on nanocarrier protection from in vivo clearance Journal of Controlled Release 162 1 208 217 doi 10 1016 j jconrel 2012 06 020 PMC 3416956 PMID 22732478 Strubbe Filip Neyts Kristiaan 2017 10 19 Charge transport by inverse micelles in non polar media Journal of Physics Condensed Matter 29 45 453003 doi 10 1088 1361 648x aa8bf6 ISSN 0953 8984 PMID 28895874 S2CID 46881977 a b Li Xiaoyu Gao Yang Boott Charlotte E Winnik Mitchell A Manners Ian 2015 Non covalent synthesis of supermicelles with complex architectures using spatially confined hydrogen bonding interactions Nature Communications 6 8127 Bibcode 2015NatCo 6 8127L doi 10 1038 ncomms9127 PMC 4569713 PMID 26337527 Gould Oliver E C Qiu Huibin Lunn David J Rowden John Harniman Robert L Hudson Zachary M Winnik Mitchell A Miles Mervyn J Manners Ian 2015 Transformation and patterning of supermicelles using dynamic holographic assembly Nature Communications 6 10009 Bibcode 2015NatCo 610009G doi 10 1038 ncomms10009 PMC 4686664 PMID 26627644 Paprocki Daniel Madej Arleta Koszelewski Dominik Brodzka Anna Ostaszewski Ryszard 2018 10 22 Multicomponent Reactions Accelerated by Aqueous Micelles Frontiers in Chemistry Frontiers Media SA 6 502 doi 10 3389 fchem 2018 00502 ISSN 2296 2646 PMC 6204348 PMID 30406083 Lipshutz Bruce H Petersen Tue B Abela Alexander R 2008 03 12 Room Temperature Suzuki Miyaura Couplings in Water Facilitated by Nonionic Amphiphiles Organic Letters American Chemical Society ACS 10 7 1333 1336 doi 10 1021 ol702714y ISSN 1523 7060 PMID 18335944 Macquarrie Duncan J 2009 05 27 Organically Modified Micelle Templated Silicas in Green Chemistry Topics in Catalysis Springer Science and Business Media LLC 52 12 1640 1650 doi 10 1007 s11244 009 9301 6 ISSN 1022 5528 S2CID 98477345 Ji Yangyuan Niu Junfeng Fang Yuhang Tan Nou Alliyan Warsinger David M 2021 Micelles inhibit electro oxidation degradation of nonylphenol ethoxylates Chemical Engineering Journal Elsevier BV 430 133167 doi 10 1016 j cej 2021 133167 ISSN 1385 8947 S2CID 239937828 Chen Xi An Yingli Zhao Dongyun He Zhenping Zhang Yan Cheng Jing Shi Linqi August 2008 Core Shell Corona Au Micelle Composites with a Tunable Smart Hybrid Shell Langmuir 24 15 8198 8204 doi 10 1021 la800244g PMID 18576675 Retrieved from https en wikipedia org w index php title Micelle amp oldid 1140514042, wikipedia, wiki, book, books, library,

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