Relaxivities of paramagnetic liposomes: on the importance of the chain type and the length of the amphiphilic complex

Nuclear magnetic relaxation dispersion (NMRD) profiles of unilamellar DPPC liposomes incorporating Gd-DTPA-bisamides with alkyl chains of 12 to 18 C atoms in their external and internal layers were recorded in order to study the influence that the chain length and structure of Gd-bisamides incorporated in the liposomal membrane have on their proton relaxivity. The NMRD profiles recorded at 310 K show that the relaxivity reaches a minimum value when the carbon chain lengths of the phospholipid and of the Gd complex match and is at a maximum in the presence of a carbon-carbon double bond. For these DPPC paramagnetic liposomes, the longer the aliphatic chains of the complex, the larger will be its immobilization in the membrane. In addition, the presence of an unsaturated carbon-carbon bond in the alkyl chain of the Gd complex induces an increase of its mobility and of its water exchange rate with, as a result, a much greater efficiency as an MRI contrast agent.     

Solvent H NMRD study of biotinylated paramagnetic liposomes containing Gd-bis-SDA-DTPA or Gd-DMPE-DTPA

The relaxometric properties of two biotinylated paramagnetic liposomes with different lipophilic complexes have been investigated by water proton nuclear magnetic resonance dispersion. The proton relaxivity was found to have a peak at the proton Larmor frequencies generally used in MRI, and to be largely affected by the residence lifetime of the water molecule in the coordination site of the metal chelate. The measurements also indicate that a local motion in the nanosecond time scale, i.e. much faster than the rotational time of the whole liposome, is effective. Possible explanations for this behavior are discussed, that may provide guidelines for the design of second-generation paramagnetic liposomes as contrast agents.     

Synthesis and characterization of multifunctional hyperbranched polyesters as prospective contrast agents for targeted MRI

Based on a commercially available hyperbranched aliphatic polyester, novel multifunctional gadolinium complexes were prepared bearing protective PEG chains, a folate targeting ligand and EDTA or DTPA chelate moieties. Their relatively high water relaxivity values coupled with biodegradability of the hyperbranched scaffold, folate receptor specificity render these non-toxic dendritic polymers promising candidates for MRI applications.     

From monomers to micelles: investigation of the parameters influencing proton relaxivity

17O NMR and (1)H NMRD studies have been performed on a series of Gd(III) 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA) derivatives as potential liver-specific magnetic resonance imaging (MRI) contrast agents. They bear aliphatic side chains which make them capable of micellar self-organization. The compounds differ in the length (C10-C18) and in the chemical nature (alkyl or monoamide-alkyl) of their lipophilic chain. We have established a convenient method to determine the critical micellar concentration (cmc) of paramagnetic surfactants by (1)H relaxivity measurements. This technique can be easily used over a large temperature range; thus, it can find wide application outside the field of MRI contrast agents. The knowledge of the cmc allowed us to determine the parameters governing the water proton relaxivity of the Gd(III) chelates in both nonaggregated and aggregated micellar forms. The relaxation data of the micellar complexes have been interpreted with the Lipari-Szabo approach. This model allows a local motion to be separated from the global tumbling of the whole micelle (modulated by a local, tau(l), and a global, tau(g), rotational correlation time, respectively). The aggregation substantially affects the rotational dynamics and thus increases the proton relaxivity of the Gd(III) chelates. The global rotational correlation times increase with increasing length of the side chain (500-2800 ps for C10-C18). Local motions are also influenced by the length and by the hydrophobicity of the side chain. The analysis of the relaxation data reveals considerable flexibility for these micellar aggregates. The rate of water exchange obtained for these chelates is identical to that for [Gd(DOTA)(H(2)O)](-) (k(ex)(298)= 4.8 x 10(6)s(-1))and is not sensitive either to micellization or to differences in the aliphatic chain. A relaxivity gain in such systems could be attained by simultaneously optimizing the water exchange by modifications of the chelate and increasing the micelle rigidity by using water-soluble surfactants with more hydrophobic side chains.     

Mn~(2+)和Cu~(2+)与脂质体和脂酶体相互作用的ESR研究

用ESR实验研究了Mn~(2 )、Cu~(2 )与DOPC,DPPC,SPL,DOPA,DPPA脂质体及其与H~ -ATP酶复合体重组的脂酶体的相互作用.通过Mn~(2 )—ESR谱线强度以及Cu~(2 )—ESR谱g因子的测量得出,磷脂分子头部不同的化学组成及其脂酰链的不同状态决定了Mn~(2 )、Cu~(2 )与膜脂结合的强弱程度,通过脂质体和脂酶体中自旋标记物5NS—ESR谱的测量进一步得出Mn~(2 )的结合增大了膜脂排列的序参数,而酶复合体的嵌入都导致与膜脂结合的Mn~(2 )比例减小.因而,当Mn~(2 )与脂酶体相互作用时,膜脂的排列最终达到一个平衡状态.在中性磷脂脂酶体的膜与Mn~(2 )之间,这种相互作用不明显.     

Phase structure of liposome in lipid mixtures

Gas microbubbles present in ultrasound imaging contrast agents are stabilized by lipid aggregates that typically contain a mixture of lipids. In this study, the phase structure of the lipid mixtures that contained two or three lipids was investigated using three different methods: dynamic light scattering, ¹H NMR, and microfluidity measurements with fluorescence probes. Three lipids that are commonly present in imaging agents (DPPC, DPPE-PEG, and DPPA) were used. Two types of systems, two-lipid model systems and simulated imaging systems were investigated. The results show that liposomes were the dominant aggregates in all the samples studied. The polar PEG side chains from the PEGylated lipid lead to the formation of micelles and micellar aggregates in small sizes. In the ternary lipid systems, almost all the lipids were present in bilayers with micelles absent and free lipids at very low concentration. These results suggest that liposomes, not micelles, contribute to the stabilization of microbubbles in an ultrasound imaging contrast agent.     

New Dual Mode Gadolinium Nanoparticle Contrast Agent for Magnetic Resonance Imaging

Background

Liposomal-based gadolinium (Gd) nanoparticles have elicited significant interest for use as blood pool and molecular magnetic resonance imaging (MRI) contrast agents. Previous generations of liposomal MR agents contained gadolinium-chelates either within the interior of liposomes (core-encapsulated gadolinium liposomes) or presented on the surface of liposomes (surface-conjugated gadolinium liposomes). We hypothesized that a liposomal agent that contained both core-encapsulated gadolinium and surface-conjugated gadolinium, defined herein as dual-mode gadolinium (Dual-Gd) liposomes, would result in a significant improvement in nanoparticle-based T1 relaxivity over the previous generations of liposomal agents. In this study, we have developed and tested, both in vitro and in vivo, such a dual-mode liposomal-based gadolinium contrast agent.

Methodology/Principal Findings

Three types of liposomal agents were fabricated: core-encapsulated, surface-conjugated and dual-mode gadolinium liposomes. In vitro physico-chemical characterizations of the agents were performed to determine particle size and elemental composition. Gadolinium-based and nanoparticle-based T1 relaxivities of various agents were determined in bovine plasma. Subsequently, the agents were tested in vivo for contrast-enhanced magnetic resonance angiography (CE-MRA) studies. Characterization of the agents demonstrated the highest gadolinium atoms per nanoparticle for Dual-Gd liposomes. In vitro, surface-conjugated gadolinium liposomes demonstrated the highest T1 relaxivity on a gadolinium-basis. However, Dual-Gd liposomes demonstrated the highest T1 relaxivity on a nanoparticle-basis. In vivo, Dual-Gd liposomes resulted in the highest signal-to-noise ratio (SNR) and contrast-to-noise ratio in CE-MRA studies.

Conclusions/Significance

The dual-mode gadolinium liposomal contrast agent demonstrated higher particle-based T1 relaxivity, both in vitro and in vivo, compared to either the core-encapsulated or the surface-conjugated liposomal agent. The dual-mode gadolinium liposomes could enable reduced particle dose for use in CE-MRA and increased contrast sensitivity for use in molecular imaging.     

Cryo-electron microscopy of artificial biological membranes

Vitrified synthetic phosphatidycholine liposome suspensions were studied by cryo-electron microscopy. The bilayer structure is resolved on vitrified liposome images. The packing of the aliphatic chains of the lipid within vitrified liposomes can be determined by the analysis of electron diffraction patterns. Images and electron diffraction patterns show that the structure of vitrified liposomes is related to the structure that liposomes have before vitrification. In fact, vitrified liposomes have a different structure, depending whether they are maintained before cooling at a temperature higher or lower than that corresponding to the ‘melting’ of the hydrocarbon chain of the lipids. Below the melting temperature, liposomes are formed by small domains.     

Effect of lysophosphatidylcholine on behavior and structure of phosphatidylcholine liposomes

Differential scanning calorimetry (DSC), fluorescence polarization and X-ray diffraction were per-formed to investigate the kinetics of the micellar to the lamellar phase transition of dipalmitoylphosphatidylcholine/1-palmitoylphosphatidylcholine (16:0 LPC/DPPC) liposomes at gel phase. With a 16:0 LPC concentration up to 27 mol% only the sharp main transition with relatively high enthalpy (△H) values of DPPC was observed. Increasing 16 : 0 LPC concentration, the phase transition was broadened and the transition enthalpy was decreased and finally totally disappeared. The fluorescence probes of 3AS, 9AS, 12AS, and 16AP were employed, respectively, to detect the mo-bility of various sites of carbon chains of DPPC or 16:0 LPC/DPPC liposomes. It was shown that DPPC liposomes formed in the absence of 16:0 LPC always had a fluidity gradient in both gel and liquid-crystalline phase, while in the presence of 14.1 mol% and 27.0 mol% 16:0 LPC in the mixtures, the fluidity gradient tended to disappear below 40℃:     

Liposomal mr contrast agents

Abstract

Liposomes are spheres composed of relatively non-toxic and biodegradable lipids which are useful for entrapping a variety of drugs, decreasing drug toxicity and targeting. For a number of years we have evaluated the use of liposomes as MR contrast agents. We have prepared and tested contrast agents entrapped within the internal aqueous space of liposomes as well as liposomes incorporating lipophilic contrast agents in the lipid bilayer. When chelates such as Gd-DTPA are entrapped within the internal aqueous space of lipid vesicles, delivery is primarily to the Kupffer cells and clearance is slow. Manganese ions entrapped within lipid vesicles cause more enhancement per micromole of paramagnetic ion than gadolinium. Lipophilic derivatives of manganese EDTA chelates when incorporated into liposomes confer the greatest hepatic enhancement per micromole of metal ion and have favorable clearance kinetics. An apparently hepatocyte specific liposomal MR contrast agent has been prepared based upon a lipophilic derivative of manganese EDTA, which enhances the liver and increases liver/tumor contrast to noise more than most other contrast agents per micromole of metal ion. The agent has very high relaxivity, Rl over 30 and R2 over 40 per micromole of manganese. Cardiac imaging shows pronounced blood pool enhancement with potential for myocardial perfusion imaging. Membrane bound lipophilic paramagnetic chelates hold promise as improved liposomal contrast agents for MR.     

Cardiolipin packing ability studied by grazing incidence X-ray diffraction

We report a grazing incidence X-ray diffraction (GIXD) study of pure and mixed Langmuir monolayers of tetramyristoyl cardiolipin (TMCL) and dipalmitoylphosphatidylcholine (DPPC) at 22 degrees C. The mixing behavior of the two components was investigated at two different surface pressures, 4 and 25mNm(-1). Cardiolipins are found to be in a liquid-condensed (LC) phase at 4mNm(-1) whereas the DPPC molecules appear disordered. At 25mNm(-1), cardiolipins are in a solid phase with their aliphatic chains perpendicular to the interface whereas the DPPC molecules are in the LC phase. At this surface pressure, increasing the amounts of TMCL to DPPC leads to a reduction in tilt angle of the aliphatic chains from nearly 30 degrees for pure DPPC to almost 0 degrees in a 1:1 molar ratio of DPPC and TMCL. At this composition, we also found the closest packing of the aliphatic chains. Further increase of the amount of TMCL does not change the lattice or the tilt and the thermodynamic analysis confirms a partial phase separation. Such a behavior was not observed at 4mNm(-1) where the two phospholipids are miscible at all the compositions studied. Addition of TMCL clearly induces a structuring of the mixed monolayers and increases order by a tight packing in the lipid acyl chains.     

Novel cationic vesicle platform derived from vernonia oil for efficient delivery of DNA through plant cuticle membranes

Novel cationic amphiphilic compounds were prepared from vernonia oil, a natural epoxidized triglyceride, and studied with respect to vesicle formation, encapsulation of biomaterials such as DNA, and their physical stability and transport through isolated plant cuticle membranes. The amphiphiles studied were a single-headed compound III (a quaternary ammonium head group with two alkyl chains) and a triple-headed compound IV, which is essentially three molecules of compound III bound together through a glycerol moiety. Vesicles of the two amphiphiles, prepared by sonication in water and solutions of uranyl acetate or the herbicide 2,4-D (2,4-dichloropenoxy acetic acid), were examined by TEM, SEM, AFM, and confocal laser systems and had a spherical shape which encapsulated the solutes with diameters between 40 and 110 nm. Vesicles from amphiphile IV could be made large enough to encapsulate a condensed 5.2kb DNA plasmid (pJD328). Vesicles of amphiphile IV were also shown to pass intact across isolated plant cuticle membranes and the rate of delivery of encapsulated radio-labeled 2,4-D through isolated plant cuticle membranes obtained with these vesicles was clearly greater in comparison to liposomes prepared from dipalmitopyl phosphatidylcholine (DPPC) and the control, nonencapsulated 2,4-D. Vesicles from amphiphiles III and IV were found to be more stable than those of liposomes from DPPC. The data indicate the potential of vesicles prepared from the novel amphiphile IV to be a relatively efficient nano-scale delivery system to transport DNA and other bioactive agents through plant biological barriers. This scientific approach may open the way for further development of efficient in vivo plant transformation systems.     

Phospholipase C and the physical states of polar head groups of lipids

Summary Activity of phospholipase C fromClostridium perfringens on liposomes made fromsn-3-phosphatidylcholine, dimyristoyl (DMPC), dipalmitoyl (DPPC) or distearoyl (DSPC) was measured at various temperatures and was correlated with their gel/liquid-crystalline phase transitions (T _c : 23, 41.5, 52°C for DMPC, DPPC, DSPC, respectively). In all cases, the activity of phospholipase C was high in the gel phases of the substrates and was almost zero in their liquid-crystalline phases. Fluorescence depolarization measurements of N-dansyl-sn-3-phosphatidylethanolamine (DPE) and 1,6-diphenyl-1,3,5-hexatriene (DPH) incorporated into the liposomes showed that both the head group and the alkyl chains of the lipids were immobilized in the gel phases but were highly mobile in the liquid-crystalline phase. These results indicate that the rotational mobility of lipids (both of the head groups and the alkyl chains) was not a major factor in the phospholipase C reaction. It is inferred that some electrostatic and/or hydrophobic interactions might play important roles in regulation of the phospholipase C activity.     

Spectroscopic and calorimetric studies on trazodone hydrochloride–phosphatidylcholine liposome interactions in the presence and absence of cholesterol

The interaction of antidepressant drug trazodone hydrochloride (TRZ) with dipalmitoyl phosphatidylcholine (DPPC) multilamellar liposomes (MLVs) in the presence and absence of cholesterol (CHO) was investigated as a function of temperature by using Electron Paramagnetic Resonance (EPR) spin labeling, Fourier Transform Infrared (FTIR) Spectroscopy and Differential Scanning Calorimetry (DSC) techniques. These interactions were also examined for dimyristoyl phosphatidylcholine (DMPC) multilamellar liposomes by using Electron Paramagnetic Resonance (EPR) spin labeling technique. In the EPR spin labeling studies, 5- and 16-doxyl stearic acid (5-DS and 16-DS) spin labels were used to monitor the head group and alkyl chain region of phospholipids respectively. The results indicated that TRZ incorporation causes changes in the physical properties of PC liposomes by decreasing the main phase transition temperature, abolishing the pre-transition, broadening the phase transition profile, and disordering the system around the head group region. The interaction of TRZ with unilamellar (LUV) DPPC liposomes was also examined. The most pronounced effect of TRZ on DPPC LUVs was observed as the further decrease of main phase transition temperature in comparison with DPPC MLVs. The mentioned changes in lipid structure and dynamics caused by TRZ may modulate the biophysical activity of membrane associated receptors and in turn the pharmacological action of TRZ.     

Liposomes and Micelles to Target the Blood Pool for Imaging Purposes

Abstract

The blood pool is among body compartments of a special interest for imaging using magnetic resonance (MR) and computed tomography (CT), since with the help of selective blood-pool contrast agents blood perfusion and various cardiac parameters as well as a status of the blood flow and vascular system in any organ can be evaluated. Blood pool-specific imaging agents can also provide minimally invasive angiography, image guidance of minimally invasive procedures, oncologic imaging of angiogenesis, ascertaining organ blood volume, and identifying hemorrhage. Particulate contrast agents (such as liposomes and micelles) whose distribution is limited to the blood pool, should have a size larger than fenestrated capillaries (> 10 nm), contain the reporter (paramagnetic or radiopaque) moiety structurally incorporated within the particulate, and be able to stay in the blood long enough to obtain clinically useful images. We describe here a new generation of long-circulating Gd-loaded liposomes and iodine-loaded micelles to provide an efficient blood pool MR and CT imaging, respectively. In this study, we developed the optimized protocol to prepare a liposomal MR contrast agent with high relaxivity and narrow size distribution. Liposomes were loaded with Gadolinium (Gd) via so called polychelating amphiphilic polymer (PAP) that represents a low-molecular-weight DTPA-polylysine linked via its N-terminus to a lipid anchor, NGPE-PE. Gd-containing liposomes were additionally modified with PEG to provide the longevity in vivo. We demonstrated also that upon the intravenous administration in rabbits and dogs, a new preparation causes prolonged decrease in the blood Tl value, permits to obtain sharp and clear MR images of the vasculature, and may be considered as a potential contrast agent for MRI of the blood pool. In addition, to prepare micellar contrast agents for CT blood-pool imaging, we synthesized an iodine-containing amphiphilic block-copolymer consisting of methoxypoly(ethyleneglycol) and polyl?,N-(triiodobenzoyl)]-L-lysine. In aqueous solutions, it forms stable micelles with an average diameter of 80 nm and an iodine content of 35–40% wt. Iodine-containing micelles were intravenously injected into rats and rabbits at a dose of 170 mg I/kg and produced significant and sustained enhancement of the blood pool (aorta and heart), liver and spleen for a period of at least 3 hours providing clear and informative CT images.     

Thermotropic phase behavior of DPPC liposome systems in the presence of the anti-cancer agent ‘Ellipticine’

This letter presents our first results on the structural changes in DPPC multilamellar vesicles dispersed in water in the presence of the anti-cancer agent Ellipticine. The thermotropic phase transitions of the lamellar packing inside lipid vesicles were characterized in situ by small angle X ray diffraction. The results lead to the determination of a critical concentration value for drug loading on the vesicle system around 4% molar fraction of Ellipticine, an indication of the localization of the drug in the alkyl chains and the influence of the drug on the decreasing rate of the bilayer period after the main phase transition.     

Paramagnetic water-soluble metallofullerenes having the highest relaxivity for MRI contrast agents.

Water-soluble gadolinium (Gd) endohedral metallofullerenes have been synthesized as polyhydroxyl forms (Gd@C(82)(OH)(n)(), Gd-fullerenols) and their paramagnetic properties were evaluated by in vivo as well as in vitro for the novel magnetic resonance imaging (MRI) contrast agents for next generation. The in vitro water proton relaxivity, R(1) (the effect on 1/T(1)), of Gd-fullerenols is significantly higher (20-folds) than that of the commercial MRI contrast agent, Magnevist (gadolinium-diethylenetriaminepentaacetic acid, Gd-DTPA) at 1.0 T close to the common field of clinical MRI. This unusually high proton relaxivity of Gd-fullerenols leads to the highest signal enhancement at extremely lower Gd concentration in MRI studies. The strong signal was confirmed in vivo MRI at lung, liver, spleen, and kidney of CDF1 mice after i.v. administration of Gd-fullerenols at a dose of 5 micromol Gd/kg, which was 1/20 of the typical clinical dose (100 micromol Gd/kg) of Gd-DTPA.     

Micelles by self-assembling peptide-conjugate amphiphile: synthesis and structural characterization

The chemical synthesis by solid-phase methods of a novel amphiphilic peptide, peptide-conjugate amphiphile (PCA), containing in the same molecule three different functions: (i) the N,N-bis[2-[bis(carboxy-ethyl)amino]ethyl]-L-glutamic acid (DTPAGlu) chelating agent, (ii) the CCK8 bioactive peptide, and (iii) a hydrophobic moiety containing four alkyl chains with 18 carbon atoms each, is reported. In water solution at pH 7.4, PCA self-assembles in very stable micelles at very low concentration [critical micellar concentration (cmc) values of 5 x 10(-7) mol kg(-1)] as confirmed by fluorescence spectroscopy. The structural characterization, obtained with small-angle neutron scattering (SANS) measurements, indicates that the aggregates are substantially represented by ellipsoidal micelles with an aggregation number of 39 +/- 2 and the two micellar axes of about 52 and 26 A.     

Interaction of liposomes with homologous series of fluorescent berberine derivatives: New cationic probes for measuring membrane potential

The interaction of liposomes with a series of fluorescent berberine derivatives having different alkyl chain lengths has been investigated. The hydrophobicity of the binding site on the phospholipid membrane increases and mobility decreases with the length of the alkyl chain. If lauryl sulphate micelles are used to bind berberines, the hydrophobicity of the binding site is the same for all derivatives. The dye series represents a model with constant charge and growing lipophilicity. Both electrostatic forces and lipophilicity play an important role in binding. By virtue of the excellent sensitivity of the dyes to medium polarity, berberines prove to be suitable probes for measuring membrane potential, but only in cases when a negative charge is generated in the liposomal interior. The fluorescence response is a linear function of the potential magnitude.     

Raman spectroscopic characteristics of microcosmic and photosensitive damage on space structure of liposomes sensitized by hypocrellin and its derivatives

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