The potential of pectin as a stabilizer for liposomal drug delivery systems

The aim of the present study was to investigate the potential of different types of pectin as stabilizers for liposomal drug delivery systems. Positively charged liposomes were coated with commercially available and purified low-methoxylated (LM), high-methoxylated (HM) and amidated (AM) pectins. The samples were stored for up to 12 weeks at 4°C, at room temperature and at 35°C. The change in liposomal size and size distribution, zeta potential, pH, leakage of encapsulated carboxyfluorescein (CF), and lipid degradation were studied. All the types of pectin were found to protect the liposomes against aggregation during storage. The pectin coat did not affect the permeability of the liposome membrane. HM and LM pectin seemed to be the most promising types of pectin due to minimal changes in the zeta potentials during storage for these samples and no detectable lipid degradation. It is concluded that pectin may be used for stabilizing liposomal drug delivery systems.     

Peroxidation of liposomal lipids

Free radicals, formed via different mechanisms, induce peroxidation of membrane lipids. This process is of great importance because it modifies the physical properties of the membranes, including its permeability to different solutes and the packing of lipids and proteins in the membranes, which in turn, influences the membranes’ function. Accordingly, much research effort has been devoted to the understanding of the factors that govern peroxidation, including the composition and properties of the membranes and the inducer of peroxidation. In view of the complexity of biological membranes, much work was devoted to the latter issues in simplified model systems, mostly lipid vesicles (liposomes). Although peroxidation in model membranes may be very different from peroxidation in biological membranes, the results obtained in model membranes may be used to advance our understanding of issues that cannot be studied in biological membranes. Nonetheless, in spite of the relative simplicity of peroxidation of liposomal lipids, these reactions are still quite complex because they depend in a complex fashion on both the inducer of peroxidation and the composition and physical properties of the liposomes. This complexity is the most likely cause of the apparent contradictions of literature results. The main conclusion of this review is that most, if not all, of the published results (sometimes apparently contradictory) on the peroxidation of liposomal lipids can be understood on the basis of the physico-chemical properties of the liposomes. Specifically: (1) The kinetics of peroxidation induced by an “external” generator of free radicals (e.g. AAPH) is governed by the balance between the effects of membrane properties on the rate constants of propagation (k _p) and termination (k _t) of the free radical peroxidation in the relevant membrane domains, i.e. in those domains in which the oxidizable lipids reside. Both these rate constants depend similarly on the packing of lipids in the bilayer, but influence the overall rate in opposite directions. (2) Peroxidation induced by transition metal ions depends on additional factors, including the binding of metal ions to the lipid–water interface and the formation of a metal ions-hydroperoxide complex at the surface. (3) Reducing agents, commonly regarded as “antioxidants”, may either promote or inhibit peroxidation, depending on the membrane composition, the inducer of oxidation and the membrane/water partitioning. All the published data can be explained in terms of these (quite complex) generalizations. More detailed analysis requires additional experimental investigations. Dedicated to Prof. K. Arnold on the occasion of his 65th birthday.     

Tannic acid-metal salt sequences for light and electron microscopic localization of complex carbohydrates.

Use of tannic acid (TA), in sequence with ferric chloride, uranyl acetate or gold chloride resulted in staining of selective but sometimes different sites in paraffin sections. TA-uranyl acetate of TA-ferric chloride stained sites rich in complex carbohydrates, wherease TA-gold chloride stained the collagen of various connective tissues different shades of red-purple to gray-black. Applied to epoxy-embedded thin sections of tissues fixed with glutaraldehyde and not post-osmicated, TA-uranyl acetate and TA-ferric chloride imparted density to subcellular sites known to contain a high concentration of mucosubstances, such as secretory granules and cisternae of the Golgi complex of certain cells. TA-gold chloride proved unsatisfactory for ultracytochemistry because of its tendency to form globular precipitates on thin sections. The effect of blockage procedures at the light microscopic level indicated that vicinal glycols are not required for binding of TA to tissue sites. Electrostatic forces were shown to be of minimal significance, whereas hydrogen bonding appeared to play a part in both TA-tissue and TA-metal binding mechanisms.     

Tannic acid as an electron-dense probe in the testis.

The use of tannic acid to preserve and promote the staining of protein constituents of the extracellular fluid is described. Its usefulness for delineating the extracellular compartment and detecting changes in capillary permeability is illustrated in experiments on the testis.     

Method of treating leukocytes for electron microscopic research

A technique of pretreatment of leukocytes and other cellular suspensions for the electron microscopic studies in suggested. Cells fixed in a suspension are embedded in a warm gelatine solution. Upon cooling, a gelatinous block that can be cut into small pieces is formed. These pieces are fixed in glutaraldehyde solution and used thereafter as pieces of dense tissues. The technique provides a better preservation of leukocyte structure, considerably facilitating ultratomy.     

Characterisation of three novel cationic lipids as liposomal complexes with DNA

Cationic lipids (CLs) are being increasingly exploited as transfection vectors for the delivery of DNA into eukaryotic cells. To obtain further insight to the complex formation and interactions between cationic liposomes and DNA, we characterised three novel cationic lipids, viz. bis[2-(11-phenoxyundecanoate)ethyl]-dimethylammonium bromide, N-hexadecyl-N-?10-[O-(4-acetoxy)-phenylundecanoate]ethyl?- dimethylammonium bromide, and bis[2-(11-butyloxyundecanoate)ethyl]dimethylammonium bromide. These lipids bear the same charged headgroup yet have different hydrophobic parts. Accordingly, we may anticipate their electrostatic interactions with DNA to be similar while differing in both thermal phase behaviour and physicochemical properties of their complexes with DNA. In keeping with the above all three lipids formed complexes with DNA as evidenced by light scattering, fluorescence spectroscopy and Langmuir film balance. Differential scanning calorimetry revealed very different phase behaviours for the binary mixtures of the three CLs with dimyristoylphosphatidylcholine and also provided evidence for DNA-induced lipid phase separation. These data were confirmed by compression isotherms and fluorescence microscopy of monolayers residing on an aqueous buffer, recorded both in the presence and absence of DNA. Importantly, binding to cationic liposomes appears to prevent thermal denaturation of DNA upon heating of the complexes. Likewise, renaturation of heat-treated DNA complexed with the cationic liposomes appears to be abolished as well.     

Lanthanum as an electron microscopic stain

Applications of lanthanum as an electron microscopic tracer have been reviewed. This electron-dense trivalent cation, which binds avidly to calcium binding sites, can be used as tracer for delineating extracellular spaces and intercellular junctions. It has served as a basis for classification of junctional structures. It can also be used as a calcium probe, a tracer in studying the permeability of barriers, as an intracellular marker and as an electron microscopic stain for such membrane components as surface glycoprotein. Each of these applications may require a different methodology. Thus methodological considerations in the use of this tracer have also been reviewed. The recent recognition that lanthanum is more than a passive tracer and that by reacting with different cell components may serve as a true stain, will extend the use of lanthanum in electron microscope histochemistry.     

BspRI methyltransferase as a marker for electron microscopic physical mapping

An approach is described in this paper for direct physical mapping of DNA by electron microscopy. It implies visualization of specific DNA-methyltransferase complexes followed by computer analysis of electron micrographs. The BspRI methylase (recognition site GGCC) was used as a marker owing to the large difference (at least three orders of magnitude) between its specific and non-specific interation with DNA, as revealed by the gel retardation technique. For electron microscopic mapping the optimum conditions were established in order to produce the maps practically without non-specific noise. The approach was tested with well-characterized plasmid DNAs—pA03, pUC19 and pBR322 carrying 4, 11 and 22 GGCC sites respectively. The results were analyzed and the applications of the method are discussed.     

Fixation of early ascarid embryos for electron microscopic research

Ascaris embryos represent a classical object in embryology, but their ultrastructure has not been so far studied because their sheets are not permeable to fixatives used for electron microscopy. Thus, the fixation with glutaraldehyde for 24 hours followed by a 24 hour OsO4-fixation led to osmification of 1% embryos. The osmification of 100% embryos was achieved after addition of detergents, sodium dodecylsulfate or Triton X-100 to aldehyde fixative. The best fixation was povided using sodium dodecylsulfate judging from ultrastructure preservation.     

Role of nicotinic acid as modulator of liposomal microviscosity

Using the fluorescent probe 1,6-diphenyl-1,3,5 hexatriene, we have investigated the effect of nicotinic acid, a derivative of the toxic alkaloid nicotine, on the fluidity profile and activation energy of diffusion in the liposomal system of several lipids. We have also studied how the fluidizing property of nicotinic acid affects the intermediate fluid condition induced by cholesterol in these liposomal systems     

Fatty acid composition of Leptospira lipids as a taxonomic criterion

The fatty-acid composition of microbial cells in 17 pathogenic and saprophytic Leptospira strains, comprising 14 serovars and 10 serogroups, has been studied. The strains under investigation have proved to fall into 3 groups differing by this characteristic. The group of saprophytic strains is characterized by a comparatively high level of myristic acid and, consequently, by the ratio of saturated and unsaturated fatty acids with 14 carbon atoms approaching 1:1; besides, it is also characterized by a lower, in comparison with the pathogenic Leptospira strains belonging to the serogroups Icterohaemorrhagiae, Canicola, Ballum has a higher level of unsaturated fatty acids. The second group of pathogenic Leptospira strains including the serogroups Grippotyphosa, Hebdomadis, Pomona, Tarassovi, Pyrogenes, Australia has been found to occupy an intermediate position between the first group of pathogenic Leptospira strains and the group of saprophytic ones. As the difference in the content of myristic acid in pathogenic and saprophytic Leptospira strains is a stable characteristic, it can be used for the differentiation of these strains. The present investigation has revealed that the distribution of the main fatty acids in Leptospira phospholipids is similar to their distribution in Leptospira neutral lipids with the exception of unsaturated fatty acid with 14 carbon atoms, occurring mainly in phospholipids.     

Tumor delivery of liposomal doxorubicin prepared with poly-L-glutamic acid as a drug-trapping agent

Context: Poly-l-glutamic acid (PGA) is an anionic polymer with a large number of carboxyl groups that can interact electrostatically with cationic drugs such as doxorubicin (DOX).

Objective: For stable encapsulation of DOX into liposomes, we prepared triethylamine (TEA)-PGA-liposomes using PGA as an internal trapping agent.

Methods: We prepared TEA-PGA-liposomes by remote loading of DOX with a TEA gradient into preformed liposomes prepared with 1, 2, or 4?mg/mL PGA (molecular weights 4800, 9800, and 20 500), and evaluated their biodistribution and antitumor effects on Lewis lung carcinoma (LLC) tumor-bearing mice.

Results: TEA-PGA-liposomes using the higher the molecular weight or concentration of PGA showed a slower release of DOX from the liposomes. TEA-PGA-liposomes prepared with a high concentration of PGA could enhance DOX accumulation in tumors and prolonged DOX circulation in the serum, indicating that DOX may be retained stably in the liposomal interior by interaction with PGA. Furthermore, injection of TEA-PGA-liposomes prepared with 4?mg/mL of PGA₉₈₀₀ or 2?mg/mL PGA₂₀₅₀₀ strongly inhibited tumor growth in LLC tumor-bearing mice.

Conclusions: PGA may be a potential trapping agent for liposomal DOX for tumor drug delivery.     

Ascorbic acid: useful as a buffer agent and radiolytic stabilizer for metalloradiopharmaceuticals

The goal of this study is to explore the use of ascorbic acid (AA) as a buffer agent and a radiolytic stabilizer for preparation and stabilization of radiolabeled DOTA-biomolecule conjugates. Results from a titration experiment show that 0.1 M AA solution has sufficient buffer capacity at pH 5.0 while 0.5 M AA solution is useful even at pH 6.0. The radiolabeling experiment using TA138, a DOTA-conjugated nonpeptide integrin alpha(v)beta(3) receptor antagonist, clearly demonstrates that AA is a good buffer agent for pH control and an excellent antioxidant for stabilization of metal-labeled diagnostic ((111)In) and therapeutic ((90)Y and (177)Lu) radiopharmaceuticals if the radiolabeling is performed at pH 5-6. There is no need for the additional stabilizer (e.g., gentisic acid) and buffer agent such as ammonium acetate. The anaerobic AA formulation described in this study is particularly useful for radiolabeling of small biomolecules, which are sensitive to the radiolytic degradation during radiolabeling.     

Platinum-pyrimidine complexes for electron microscopic cytochemistry of deoxyribonucleic acid.

Platinum-pyrimidine complexes that are amorphous and highly soluble in water when used as sole electron-dense stains show high selectivity for nucleic acid-rich areas like chromatin, nucleolus and ribosomes. A method is presented for the selective staining of deoxyribonucleic acid. Glutaraldehyde-fixed tissue are exposed to 3 N HCL hydrolysis for an optimum time of 1 hr at room temperature before being embedded in Epon. Thin sections are then exposed to Schiff's reagent for 30 min and treated with 1% platinum-pyrimidine complex. The results inselective staining of structures containing deoxyribonucleic acid.     

Tannic acid characterized membranes of animal cells

Summary Tannic acid affects one face of some cytoplasmic membranes causing them to appear thin in electron micrographs.Trans vesicles of Golgi apparatus, dictyosome-like-structures, headcaps and aerosomes of germ cells, and certain lysosomes all have membranes that appear thin after tannic acid fixation and, in addition, are all characterized as being acid phosphatase positive. Thus, thin membranes appear functionally related and to be associated with cellular components that have lysosome or lysosome-like character.     

Tannic acid in histology: an historical perspective

The development of tannic acid as a reagent in histological methods is traced against a background of widespread use in science and technology from times of antiquity. Numerous light microscopic methods involving tannic acid, particularly in conjunction with iron and silver, have been described for a variety of tissue components. In most applications, tannic acid functions as a mordant. Current use is generally restricted to methods based on its affinity for collagen. The most significant histological use of tannic acid in contemporary times is as an adjunct to conventional glutaraldehyde-osmium-heavy metal fixation and staining for ultrastructural studies of tissue structures not normally clearly demonstrated. Tannic acid reacts with various components by mechanisms which are often not fully understood.