Macromolecule-to-Amphiphile Conversion Process of a Polyoxometalate-Polymer Hybrid and Assembled Hybrid Vesicles

We report our findings on the macromolecule-to-amphiphile conversion process of a polyoxometalate-polymer hybrid and the assembled hybrid vesicles formed by aggregation of the hybrid amphiphile. The polyoxometalate-polymer hybrid is composed of a polyoxometalate (POM) cluster, which is covered by five tetrabutylammonium (Bu(4) N(+) ) countercations, and a polystyrene (PS) chain. Through a cation-exchange process the Bu(4) N(+) countercations can be replaced by protons to form a hybrid amphiphile composed of a hydrophilic, protonated POM cluster and a hydrophobic PS chain. By implementing a directed one-dimensional diffusion and analyzing the diffusion data, we confirmed that the diffusion of solvated protons rather than macromolecules or aggregates is the key factor controlling the conversion process. Once the giant hybrid amphiphiles were formed, they immediately assembled into kinetically favored vesicular aggregates. During subsequent annealing these vesicular aggregates were transformed into thermodynamically stable vesicular aggregates with a perfect vesicle structure. The success in the preparation of the POM-containing hybrid vesicles provides us with an opportunity of preparing POM-functionalized vesicles.     

Macromolecule-to-Amphiphile Conversion Process of a Polyoxometalate–Polymer Hybrid and Assembled Hybrid Vesicles

We report our findings on the macromolecule-to-amphiphile conversion process of a polyoxometalate–polymer hybrid and the assembled hybrid vesicles formed by aggregation of the hybrid amphiphile. The polyoxometalate–polymer hybrid is composed of a polyoxometalate (POM) cluster, which is covered by five tetrabutylammonium (Bu₄N⁺) countercations, and a polystyrene (PS) chain. Through a cation-exchange process the Bu₄N⁺ countercations can be replaced by protons to form a hybrid amphiphile composed of a hydrophilic, protonated POM cluster and a hydrophobic PS chain. By implementing a directed one-dimensional diffusion and analyzing the diffusion data, we confirmed that the diffusion of solvated protons rather than macromolecules or aggregates is the key factor controlling the conversion process. Once the giant hybrid amphiphiles were formed, they immediately assembled into kinetically favored vesicular aggregates. During subsequent annealing these vesicular aggregates were transformed into thermodynamically stable vesicular aggregates with a perfect vesicle structure. The success in the preparation of the POM-containing hybrid vesicles provides us with an opportunity of preparing POM-functionalized vesicles.     

Membrane dynamics of a myelin-like giant multilamellar vesicle applicable to a self-reproducing system

A real time observation of a myelin-like giant multilamellar vesicle (mGMV) revealed that it divided into relatively small mGMVs when an aqueous solution of an electrolyte was added. Furthermore, the mGMV showed a division process accompanied by the growth of the dividing mGMVs when a bolaamphiphile which was composed of an electrolyte unit and a vesicular amphiphile unit was added. This vesicular system can be regarded as a self-reproduction of mGMV, where the added amphiphile acts as a supplier of both the vesicular amphiphile and the division initiator.     

Reduction-responsive vesicles composed of dimethylaminopropyl octadecanamide and dithiodipropionic acid

Reduction-responsive vesicle was prepared by salt-bridging N-[3-(dimethylamino)propyl]-octadecanamide (DMAPODA, a cationic amphiphile) using 3,3′-dithiodipropionic acid (DTPA, a disulfide diacid compound). According to the transmission electron micrograph and the fluorescence quenching degree (53.2%), it could be said that vesicles were formed when the DMAPODA to DTPA molar ratio was 2:2. The DMAPODA/DTPA associate was considered to be a building block for vesicle formation because DTPA could electrostatically associate with DMAPODA and help the cationic amphiphile assemble into the vesicle. On a differential scanning calorimetric thermogram, the DMAPODA/DTPA vesicle showed two endothermic peaks at 50.6°C and 63.2°C. The peak found at the lower temperature was possibly due to the solid gel-to-liquid crystal phase transition of the vesicular membrane and the peak found at the higher temperature was considered to be due to the melting of DMAPODA, indicating that unassociated DMAPODA coexisted with DMAPODA/DTPA vesicles. The release of calcein enveloped in the vesicle was promoted by DL-dithiothreitol, possibly because DTPA can be broken by the reducing agent to form mercaptopropionic acids and the vesicle could be disintegrated and/or the vesicular membrane would become defective.     

Stabilized vesicles consisting of small amphiphiles for stepwise photorelease via UV light

A small amphiphile consisting of hydrophilic tetraethylene glycol monoacrylate and hydrophobic alkyl chain which were connected by an o-nitrobenzyl unit, a photolabile group, was designed and synthesized. The critical aggregate concentration of the synthesized amphiphile was determined to be about 3 × 10(-5) M by the fluorescence probe technique. Nanosized vesicles were prepared and stabilized by in-situ radical polymerization without altering the morphology. The polymeric vesicle was highly stable which retained vesicular shape under dilution or UV irradiation. Hydrophobic guests can be encapsulated within the vesicle membrane and released out of the vesicle by UV stimulus through splitting the amphiphilic structure of the amphiphile. Distinguished dose-controlled photorelease of the polymeric vesicle is achieved due to the maintenance of the vesicular shape integrity which makes the guest release depend on the cleavage amount of amphiphilic structure during UV irradiation. This study provides a promising strategy to develop stable drug delivery systems for sustained and phototriggered release.     

Population study of sizes and components of self-reproducing giant multilamellar vesicles

Population analysis of a system of self-reproducing giant multilamellar vesicles (GMVs) was carried out by means of flow cytometry. The multidimensional distribution of forward light scattering (FS), side light scattering (SS), and fluorescence (FL) intensities originating from each GMV provided information about changes in a population composed of 104 vesicles. FS-FL dot plots indicated that, after the addition of the membrane precursor, the size distribution of the newly generated vesicles was nearly the same as that of the original, but the catalyst content was reduced. This result can be interpreted as evidence for the occurrence of the self-reproduction of GMVs. Moreover, the new GMVs recovered the amount of catalyst to the initial value, keeping their size distribution constant, when a solution of the catalyst was added to the new GMVs. These results are the first experimental evidence for a novel phenomenon on GMV size distribution during their self-reproducing cycle.     

Autocatalytic membrane-amplification on a pre-existing vesicular surface

In water, phosphoric membrane molecule (V(-)) self-assembled to form an anionic giant vesicle, the surface of which served as a catalyst for the autocatalytic formation of V(-) from its membrane precursor (V*), and the amplified V(-) produced a new vesicle using the original vesicle as a scaffold.     

Stable vesicles composed of monocarboxylic or dicarboxylic fatty acids and trimethylammonium amphiphiles

The self-assembly of cationic and anionic amphiphile mixtures into vesicles in aqueous media was studied using two different systems: (i) decanoic acid and trimethyldecylammonium bromide and (ii) hexadecanedioic acid (a simple bola-amphiphile) and trimethyldecylammonium bromide. The resulting vesicles with varying amphiphile ratios were characterized using parameters such as the critical vesicle concentration, pH sensitivity, and encapsulation efficiency. We also produced and observed giant vesicles from these mixtures using the electroformation method and confocal microscopy. The mixed catanionic vesicles were shown to be more stable than those formed by pure fatty acids. Those containing bola-amphiphile even showed the encapsulation of a small hydrophilic solute (8-hydroxypyrene-1,3,6-trisulfonic-acid), suggesting a denser packing of the amphiphiles. Compression and kinetics analysis of monolayers composed of these amphiphiles mixtures at the air/water interface suggests that the stabilization of the structures can be attributed to two main interactions between headgroups, predominantly the formation of hydrogen bonds between protonated and deprotonated acids and the additional electrostatic interactions between ammonium and acid headgroups.     

A Versatile and Robust Vesicle Based on a Photocleavable Surfactant for Two‐Photon‐Tuned Release

A small amphiphile that contains a coumarin unit and alkynyl groups, as a two‐photon‐cleavable segment and polymerizable groups, respectively, was designed and synthesized. The amphiphile showed a critical aggregation concentration of about 4.6×10^?5 M and formed a vesicle‐type assembly. The formed vesicles were stabilized by in situ “click” polymerization without altering their morphology. Hydrophobic and hydrophilic guests can be encapsulated within the vesicle membrane and inside the aqueous core of the vesicle, respectively. The loaded guests can be released from the vesicle by using UV or near‐IR stimuli, through splitting up the amphiphilic structure of the amphiphile. Distinguished dose‐controlled photorelease of the polymeric vesicle is achieved with the maintenance of vesicular integrity, which makes the guest release dependent on the amount of cleavage of the amphiphilic structure during irradiation. This study provides a potential strategy for the development of versatile and stable drug‐delivery systems that offer sustained and photo‐triggered release.     

新型含苯硼酸和喹啉的囊泡荧光多糖传感器的制备

利用合成的含有识别基团苯硼酸和荧光读出基团喹啉的新型双亲化合物对硼酸苯甲基-8-十六烷氧基溴化喹啉(BHQB)在水中自组织成囊泡,囊泡的相变温度为52.4℃;当向囊泡体系加糖时,BHQB囊泡中的喹啉生色基在508nm的荧光峰强度急剧减弱,425nm处荧光逐渐增强.荧光强度变化可能归于所形成的硼酸酯改变了双亲化合物中硼原子的杂化轨道形式,进一步引起了整个分子内部的电子云排布所致.BHQB囊泡与糖的相互作用而导致体系荧光强度变化,并且这种变化的幅度与加入糖的种类和量均有关.因此体系有可能应用于检测生物物质如糖的化学传感器.     

检测维生素C的囊泡荧光传感器的制备

利用合成的含有识别基团苯硼酸和荧光读出基团萘的新型双亲化合物(DNMPBA)在THF/水选择性溶剂中自组织成囊泡,囊泡的相变温度为56.8℃;当向囊泡体系加维生素C时,DNMPBA囊泡中的萘生色基在345nm的荧光峰强度急剧减弱.荧光强度减弱归于所形成的硼酸酯增强了DNMPBA双亲化合物中一个氧原子孤对电子对萘生色基的淬灭作用.DNMPBA囊泡与维生素C的相互作用而导致体系荧光强度变化,使该体系有可能应用于检测生物物质如维生素C的化学传感器.     

Enhancing physical stability of positively charged catanionic vesicles in the presence of calcium chloride via cholesterol-induced fluidic bilayer characteristic

An ion pair amphiphile (IPA), hexadecyltrimethylammonium-dodecylsulfate (HTMA-DS), and a double-chained cationic surfactant, dimethyldimyristylammonium bromide (DTDAB), could form positively charged catanionic vesicles with a potential application in gene delivery. To improve the gene delivery efficiency, the addition of CaCl₂ into cationic liposomal systems has been proposed in the literature. In this study, detrimental effect of calcium chloride on the physical stability of the positively charged HTMA-DS/DTDAB catanionic vesicles was demonstrated by the size and zeta potential analyses of the vesicles. It was noted that the reduced electrostatic interaction between the catanionic vesicles could not fully explain the lowered physical stability of the vesicles in the presence of CaCl₂. Apparently, the molecular packing/interaction in the vesicular bilayers played an important role in the vesicle physical stability. To modify the molecular packing/interaction in the vesicular bilayers, cholesterol was adopted as an additive to form catanionic vesicles with HTMA-DS/DTDAB. It was found that the physical stability of the catanionic vesicles was significantly improved with the presence of cholesterol in the vesicular bilayers even in the presence of 50 mM CaCl₂. An infrared analysis suggested that with the incorporation of cholesterol into HTMA-DS/DTDAB vesicular bilayers, the alkyl chain motion was enhanced, and the molecular packing became less ordered. The cholesterol-induced fluidic bilayer characteristic allowed the vesicular bilayers to be adjusted to a stable status, resulting in improved physical stability of the catanionic vesicles even in the presence of CaCl₂ with a high concentration.     

Kinetics of breakdown of vesicles from didodecyldimethylammonium bromide induced by single chain surfactants and by osmotic stress in aqueous solution

Didodecyldimethylammonium bromide (DDAB) forms vesicles spontaneously by simple solubilization of the solid into water at a concentration of ≈2.5 mM. Vesicles can be observed by the increase in turbidity of the aqueous solution of DDAB and by the increase in absorbance (at λ_max=490 nm) of a lipophilic dye (Sudan III) solubilized into the vesicular bilayer. This vesicle system has been perturbed by addition of single-chain surfactants in order to study the transition from a vesicle-stable region to a mixed-micelle region. Vesicle breakdown involves the initial incorporation of a single-chain surfactant into the vesicular bilayer, followed by subsequent disintegration of the vesicle. The progress of reaction has been observed by monitoring turbidity changes using a stopped-flow spectrophotometer. The rate of breakdown of vesicles depends on the concentration and hydrophobic properties of the added single-chain surfactant. In addition, hypertonic and hypotonic osmotic stresses have been investigated.     

Fatty acid vesicles

Results obtained from recent studies on the preparation and application of fatty acid vesicles are reviewed, focusing on some of the particular properties of fatty acid vesicles in comparison with conventional phospholipid vesicles (liposomes): (i) pH dependency which allows reversible transformations from non-vesicular to vesicular aggregates, and (ii) dynamic features that place fatty acid vesicles in between conventional vesicles formed from double-chain amphiphiles and micelles formed from single-chain surfactants. There are two main research areas in which fatty acid vesicles have been studied actively during the last years: (i) basic physico-chemical properties, and (ii) applications as protocell models. Applications of fatty acid vesicles in the fields of food additives and drug delivery are largely unexplored, which is at least partially due to concerns regarding the colloidal stability of fatty acid vesicles (pH- and divalent cation-sensitivity). Recently, fatty acid vesicles were prepared from highly unsaturated fatty acids (docosahexaenoic acid) and the pH range of vesicle formation could be extended to high or low pH values by preparing mixed vesicles through addition of a second type of single-chain amphiphile that stabilizes the vesicle bilayer but itself is not a fatty acid.     

Condensation properties of vesicles formed from an amphiphilic N-phosphorylamino acid

Stable unilamellar vesicles were formed in water under appropriate pH from dispersions of N-(O,O-di-n-hexadecyl)phosphorylalanine, an amphiphilic N-phosphorylamino acid. We found that condensation occurred in the vesicle solution after incubated at 40 degrees C, which may contribute to the stability of the vesicular system. Dipeptide derivative in the vesicle solution was identified by electrospray ionization mass spectrometry (ESI-MS), which suggests the peptide formation without any coupling reagents. Hydrogen bond and electrostatic interactions play important roles in the process of vesicle formation, while the suitable orientation and packing of the amphiphilic molecules at the vesicle/water interface together with certain conformational freedom in the vesicular bilayer are considered to be most favorable for the condensation in ordered systems as vesicles.     

Fluorescence microscopic investigation on morphological changes of giant multilamellar vesicles induced by amphiphilic additives

Adding an artificial bolaamphiphile to a dispersion of giant multilamellar vesicles (GMVs) made of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphatidylcholine (POPC) induced a cup-shaped deformation in GMVs accompanied by partial extrusion of the inner vesicle; thereafter, the deformed vesicles returned to their original shape. On the other hand, when the artificial bolaamphiphile together with a surfactant was added to the vesicular dispersion, these deformation and reformation dynamics were transmitted from the outer membranes in GMVs to the inner membranes until an intact inner vesicle was extruded out of the outer membrane. The microscopic aspects of these processes were investigated using amphiphiles tagged with individual fluorophores.     

新型含苯硼酸和萘双亲化合物的合成与囊泡荧光传感器的制备

合成了含有识别基团苯硼酸和荧光基团萘的新型对-[(5-十二烷氧基-1-氧基)萘]甲基苯硼酸{p-[(5-dodecyloxy-1-oxy) naphthalene] methyl-phenylboronic acid, DNMPBA}双亲化合物; 该化合物在THF/水选择性溶剂中自组织成囊泡, 囊泡的相变温度为56.8 ℃; 当向囊泡体系加糖时, DNMPBA囊泡中的萘生色基在345 nm的荧光峰强度急剧增强; 荧光强度随添加不同糖的变化趋势为果糖>葡萄糖>麦芽糖>乙二醇. 荧光强度增强可能归因于所形成的硼酸酯减弱了DNMPBA双亲化合物中一个氧原子孤对电子对萘生色基的猝灭作用而使荧光强度重新恢复. DNMPBA囊泡与糖的相互作用导致体系荧光强度变化, 使该体系有可能应用于检测生物物质如糖的化学传感器.     

Phase evolution,structural characteristics and mechanism of vesicle formation from a synthetic amphiphile: Controlled morphology by tuning solution phase parameters

We report herein, the aggregation behavior of 3, 4-di(dodecyloxy)benzoic acid-4-hydroxy phenyl ester (DDBE), a synthetic amphiphile and a true non-ionic surfactant system as per the geometrical considerations. The true surfactant nature of the system stems from its hydrophilic-lipophilic-balance (HLB?=?4.7), comparable to that of Span-60, also a true non-ionic surfactant. This compound undergoes spontaneous vesicle formation in THF:water binary solvent mixtures which further underwent fission at lower DDBE concentrations and fusion at higher concentrations, leading to giant vesicles of the order of 3000?nm. These vesicles are sensitive to the polarity of their environment. The predominant mode of interaction as observed from the molecular dynamics simulations were found to be π-π stacking with the phenyl rings of the molecule. Further, the system, upon complete extraction into water, formed spherical aggregates of size 50?nm based on the good solvent-poor solvent combination as the necessary condition for the vesicle formation.GRAPHICAL ABSTRACT     

Photostimulated vectorial electron transfer across the bilayer membrane of lipid vesicles in a system with CdS nanoparticles as photosensitizer and 1,4--bis(1,2,6-triphenyl-4-pyridyl)benzene as a reversible two-electron carrier

Photostimulated vectorial electron transfer through the lecithin bilayer membrane was studied in a system based on lipid vesicles with CdS as a photosensitizer located either in the vesicle inner cavity or outside the vesicles. 1,4-Bis(1,2,6-triphenyl-4-pyridyl)benzene (benzoviologen) was used as an effective lipophilic highly reversible electron carrier incorporated into the bilayer membrane. A peculiarity of this electron carrier is its ability to be reversibly reduced on one and two electrons. The interface electron transfer across the border “vesicular cavity-membrane” was studied by stationary and pulse photolysis. The primary photoreduced form of benzoviologen appears to be that reduced by one electron; however, on stationary photolysis, most benzoviologen molecules appear to be affected by two-electron reduction, which can result from the low mutual mobility of CdS nanoparticles and benzoviologen molecules. The CdS photostimulated transmembrane electron transfer from the internal sacrificial donor to the external acceptor (as regards the vesicular cavity) was performed for [CoEDTA]⁻ as the final electron acceptor. The rate constants of electron transfer from the membrane-embedded two-electron reduced form of benzoviologen have been determined in the case of [CoEDTA]⁻ and O₂ as acceptors.     

Preparation and properties of vesicles made of nonpolar/polar/nonpolar fullerene amphiphiles

Twenty potassium complexes of penta-[(4-substituted)phenyl][60]fullerene anions were synthesized and examined for their ability to form bilayer vesicles in water. The 4-substituents include alkyl groups ranging from methyl to icosanyl groups and perfluoromethyl, perfluorobutyl, and perfluorooctyl groups. The overall structure of the amphiphiles can be described as a nonpolar/polar/nonpolar (n-p-n') motif as opposed to the usual polar/nonpolar motif of lipid amphiphiles. Despite the hydrophobicity of the fullerene moiety (n-part) and alkyl/perfluoroalkyl chains (n'-part), all compounds except for the one with perfluoromethyl groups were soluble in water because of the centrally located fullerene cyclopentadienide (p-part) and spontaneously formed a vesicle of 25- to 60-nm diameter with a narrow unimodal size distribution. The vesicles are stable upon heating to 90 °C or standing over one year in air, as well as on a solid substrate in air or in vacuum, maintaining their spherical form. The vesicle membrane consists of an interdigitated bilayer of the amphiphile molecules, in which the fullerene n-part is inside and the n'-side is exposed to water. These vesicles, in particular the one bearing icosanyl chains, exhibit the smallest water permeability coefficient ever found for a self-assembled membrane in water.