Tyrosine-derived polymeric surfactant nanospheres insert cholesterol in cell membranes.

HYPOTHESIS: The design of biodegradable tyrosine-derived polymeric surfactants (TyPS) through the use of calculated thermodynamic parameters could lead to phospholipid membrane surface modifiers capable of controlling cellular properties such as viability. Delivery of cholesterol by TyPS nanospheres into membrane phospholipid domains could provide further controlled modulation of membrane physical and biological properties. EXPERIMENT: Calculated Hansen solubility parameters (∂T) and hydrophile:lipophile balances (HLB) were applied to design and synthesize a small family of diblock and triblock TyPS with different hydrophobic blocks and PEG hydrophilic blocks. Self-assembled TyPS/cholesterol nanospheres were prepared in aqueous media via co-precipitation. Cholesterol loading and Langmuir film balance surface pressures of phospholipid monolayers were obtained. TyPS and TyPS/cholesterol nanosphere effects on human dermal cell viability were evaluated by cell culture using poly(ethylene glycol) (PEG) and Poloxamer 188 as controls. FINDINGS: Stable TyPS nanospheres incorporated between 1% and 5% cholesterol. Triblock TyPS formed nanosphere with dimensions significantly smaller than diblock TyPS nanospheres. In accord calculated thermodynamic parameters, cholesterol binding increased with increasing TyPS hydrophobicity. TyPS inserted into phospholipid monolayer films in a manner consistent with their thermodynamic properties and TyPS/cholesterol nanospheres delivered cholesterol into the films. Triblock TyPS/cholesterol nanospheres increased human dermal cell viability, which was indicative of potentially beneficial TyPS effects on cell membrane surface properties.

Biosurfactant production by halophilic yeasts isolated from extreme environments in Botswana.

Nine morphologically distinct halophilic yeasts were isolated from Makgadikgadi and Sua pans, as pristine and extreme environments in Botswana. Screening for biosurfactant production showed that Rhodotorula mucilaginosa SP6 and Debaryomyces hansenii MK9 exhibited the highest biosurfactant activity using Xanthocercis zambesiaca seed powder as a novel and alternative inexpensive carbon substrate. Chemical characterization of the purified biosurfactants by Fourier Transform Infra-Red spectroscopy suggested that the biosurfactant from R. mucilaginosa SP6 was a rhamnolipid-type whereas the biosurfactant from D. hansenii MK9 was a sophorolipid-type. The two biosurfactants exhibited antimicrobial activities against eight pathogenic bacteria and fungal strains (Proteus vulgaris, Escherichia coli, Klebsiella pneumoniae, Staphylococcus aureus, Micrococcus luteus, Cryptococcus neoformans, Candida albicans and Aspergilus niger). The sophorolopid-type biosurfactant was found to be the most potent among the antimicrobial drug resistant strains tested. The findings open up prospects for the development of environmentally friendly antimicrobial drugs that use an inexpensive source of carbon to reduce the costs associated with the production of biosurfactants.

Oil sludge washing with surfactants and co-solvents: oil recovery from different types of oil sludges.

Different physicochemical and biological treatments have been used to treat oil sludges, and oil recovery techniques are preferred such as oil sludge washing (OSW) with surfactants and co-solvents. Toluene is commonly used as co-solvent, but it is non-benign to the environment. This study tested alternative co-solvents (n-pentane, n-hexane, cyclohexane, and isooctane) at 1:1 and 2:1 C/OS (co-solvent to oil sludge ratio). Also, this study evaluated the effect on the oil recovery rate (ORR) of three main parameters in the washing: type, concentration, and application ratio (S/OS) of surfactants to oil sludges. To date, no study has assessed these parameters in the washing of oil sludges from different sources. Four types of oil sludges and five surfactants (Triton X-100 and X-114, Tween 80, sodium dodecyl sulphate (SDS), and rhamnolipid) were used. The results showed that cyclohexane had high ORR and could be used instead of toluene because it is more benign to the environment. The S/OS ratio had a high effect on the ORR and depended on the type of oil sludge. Rhamnolipid, Triton X-100, and Triton X-114 had the highest oil recovery rates (40 - 70%). In addition, it was found that the surfactant concentration had no effect on the ORR. Consequently, the addition of surfactant was not significantly different compared to the washing with no surfactants, except for one sludge. The use of the surfactant in the washing solution can help in the selective extraction of specific oil hydrocarbon fractions in the recovered oil to assess its potential reuse as fuel. Further recommendations were given to improve the OSW process.

Formulation development of lipid nanoparticles: Improved lipid screening and development of tacrolimus loaded nanostructured lipid carriers (NLC).

Lipid nanoparticles are well-known nanocarriers for improved drug delivery. Their formulation development typically involves three formulations steps. In the first part a suitable lipid mixture which enables a high loading capacity and high encapsulation efficacy of the active needs to be identified (lipid screening). In the second step suitable stabilizers that enable the production of small-sized lipid nanoparticles with narrow size distribution and sufficient physical stability need to be identified (stabilizer screening, optimization of production parameters) and in the third step the biopharmaceutical efficacy needs to be evaluated. Based on the results obtained the formulations will require further optimization. The classical formulation development of lipid nanoparticles and especially the classical lipid screening is tedious. Therefore, in this study, a novel approach for the lipid screening that was based on the determination of the Hansen solubility parameters was evaluated and the results obtained were compared to the results from the classical model. Tacrolimus was used as a model drug. Results showed that both lipid screenings led to similar results, indicating that the new approach can be used for future developments. The optimized formulation was composed of a lipid matrix system that contained waxes, triglycerides and monoacylglycerols with various carbon chain lengths (C8, C10, C16, C18) and enabled an encapsulation efficiency of ~99%. The stabilizer screening showed that surfactants with high HLB values, lower molecular weight, and shorter alkyl chain length tended to form smaller particles with narrower size distribution and better physical stability. The most suitable surfactant was found to be a caprylyl/capryl glucoside (Plantacare® 810), a PEG-free stabilizer, that is extremely mild for atopic skin. It led to particle sizes of about 200 nm and a zeta potential well above |30| mV. The optimized formulation contained 0.1% tacrolimus and possessed good physical stability. In conclusion, an optimized method for the selection of lipids that results in a limited number of experiments could be established and tacrolimus loaded lipid nanoparticles with similar drug load as a marketed formulation was successfully developed in this study.

Detection of stealthy small amphiphilic biomarkers.

Pathogen-specific biomarkers are secreted in the host during infection. Many important biomarkers are not proteins but rather small molecules that cannot be directly detected by conventional methods. However, these small molecule biomarkers, such as phenolic glycolipid-I (PGL-I) of Mycobacterium leprae and Mycobactin T (MbT) of Mycobacterium tuberculosis, are critical to the pathophysiology of infection, and may be important in the development of diagnostics, vaccines, and novel therapeutic strategies. Methods for the direct detection of these biomarkers may be of significance both for the diagnosis of infectious disease, and also for the laboratory study of such molecules. Herein, we present, for the first time, a transduction approach for the direct and rapid (30min) detection of small amphiphilic biomarkers in complex samples (e.g. serum) using a single affinity reagent. To our knowledge, this is the first demonstration of an assay for the direct detection of PGL-I, and the first single-reporter assay for the detection of MbT. The assay format exploits the amphiphilic chemistry of the small molecule biomarkers, and is universally applicable to all amphiphiles. The assay is only the first step towards developing a robust system for the detection of amphiphilic biomarkers that are critical to infectious disease pathophysiology.

Nanoaggregates of a random amphiphilic polyanion to carry water-insoluble clofazimine in neutral aqueous media.

Clofazimine, an antibiotic drug active against mycobacteria and used for the treatment of leprosy, is a very weak base insoluble in neutral aqueous media. It may cause rather severe secondary effects. Basically, these two shortcomings can be minimized by combination with a drug carrier. The potential of a polymeric carrier composed of nanosized aggregates formed by hydrophobized poly(methyl vinyl ether-alt-maleic acid) to solubilize clofazimine in neutral aqueous media and to administer it to mice was investigated. This amphiphilic polyanion was synthesized by partial esterification of commercial poly(methyl vinyl ether-alt-maleic anhydride) by dodecanol. An aggregate-forming analog bearing mannose residues aimed at targeting mannose receptors born by macrophages was also synthesized and characterized. In the presence of the aggregates, rather large amounts of clofazimine were compatibilized with neutral aqueous media. Comparison with a water-insoluble neutral dye, namely yellow OB, showed that the apparent solubilization of clofazimine was due to a synergistic combination of electrostatic and hydrophobic interactions and not only to the latter as in the case of yellow OB. Despite its favorable in vitro characteristics, clofazimine entrapped within the lipophilic pockets born by the amphiphilic aggregates exhibited no antibiotic activity after administration to mice infected with Mycobacterium bovis BCG.

Spectrophotometric determination of dapsone in pharmaceutical products using sodium 1,2-naphthoquinone-4-sulfonic as the chromogenic reagent.

Spectrophotometric determination of dapsone is described. The dapsone reacts with sodium 1,2-naphthoquinone-4-sulfonic in pH 6.98 buffer solution to form a salmon pink compound, and its maximum absorption wavelength is at 525 nm, epsilon525=3.68 x 10(4) l mol(-1) cm(-1). The absorbance of dapsone from 0.40 to 10 microg ml(-1) obeys Beer's law. The linear regression equation of the calibration graph is C=0.2334 A + 0.01288, with a linear regression correlation coefficient of 0.9998, the detection limit is 0.24 microg ml(-1), and recovery is from 99.2 to 102.4%. Effects of pH, surfactant, organic solvents, foreign ions, and standing time on the determination of dapsone have been examined. This method is simple and can be used for the determination of dapsone in injection solution of dapsone. The results obtained by this method agreed with those by the official method (dead-stop titration method [The Chinese Pharmacopoeia, Pharmacopoeia Commission, Ministry of Health, vol. 2, fifth ed., PRC Chemical Industry Press, Beijing, 2000, p.720]).

Lipid domains of mycobacteria studied with fluorescent molecular probes.

The complex mycobacterial cell envelope is recognized as a critical factor in our failure to control tuberculosis, leprosy and other non-tuberculous pathogens. Although its composition has been extensively determined, many details regarding the organization of the envelope remain uncertain. This is particularly so for the non-covalently bound lipids, whose natural distribution may be disrupted by conventional biochemical or cytological techniques. In order to study the native organization of lipid domains in the mycobacterial envelope, we have applied a range of fluorescent lipophilic probes to live mycobacteria, including Mycobacterium smegmatis, Mycobacterium tuberculosis, Mycobacterium avium, Mycobacterium gadium and Mycobacterium aurum, and analysed the resultant signals by fluorescence microscopy and digital image processing. Five key features were observed: (i) the presence of both envelope and intracellular lipid domains; (ii) differential localization of probes into these domains influenced predominantly by their hydrophobicity, as modelled by their calculated octanol:water partition coefficients and by their amphiphilicities; (iii) uneven distribution of lipophilic material in the envelope; (iv) selective labelling of septal regions of the envelope; and (v) modification of labelling patterns by additional treatments such as fluorescence quenching antibodies, detergents and solvents. Using this last approach, a coherent cell envelope lipid domain was demonstrated outside the cytoplasmic membrane and, for the first time, the proposed covalently linked mycolyl-arabinogalactan-peptidoglycan macromolecular complex was imaged directly. The use of fluorescent probes and high-resolution fluorescence microscopy has enabled us to obtain a coherent view of distinct lipid domains in mycobacteria. Further application of this approach will facilitate understanding of the role of lipids in the physiology of these organisms.

Kinetic characterization of the normal and detergent-perturbed reaction cycles of the sarcoplasmic reticulum calcium pump. Rate-limiting step(s) under different conditions.

We previously characterized the structural features of the interaction of sarcoplasmic reticulum membranes with nonsolubilizing concentrations of C12E8, the non-ionic detergent octaethylene glycol monododecyl ether (Andersen, J.P., le Maire, M., Kragh-Hansen, V., Champeil, P., and Møller, J. V. (1983) Eur. J. Biochem. 134, 205-214). The present study characterizes especially the functional aspects and implications of the detergent-induced perturbation for an understanding of ATPase function. Perturbing detergent decreased Vmax, but left Ca2+ transport intact. Detergent incorporation affected neither the calcium-dependent phosphorylation from ATP, as judged from multimixer quenching experiments, nor the calcium-releasing transition between the two phosphoenzyme forms (Ca2E1P to E2P), as judged from kinetically resolved dual-wavelength measurements with the calcium-sensitive dye antipyrylazo III. However, the decrease in Vmax was accounted for by a decrease in the rate of enzyme dephosphorylation by a factor of 3-4, whereas the Ca2+-dependent transition between the nonphosphorylated enzyme forms (E2 to Ca2E1) was enhanced almost 10-fold. Evidence of a conformational change of E2 by C12E8 toward that of the E1 state to account for the perturbed reactions was obtained from experiments on vanadate reactivity and tryptic degradation pattern. Both direct and steady-state evidence was obtained for an acceleration by ATP of the Ca2E1P to E2P transition which may account for the low affinity modulatory effect of the nucleotide on enzyme turnover. The kinetic data indicated that reduction of ATP hydrolysis by C12E8 coincided with conditions where E2P dephosphorylation becomes rate-limiting (high ATP concentration, low pH, absence of potassium). Otherwise, the Ca2E1P to E2P transition is deduced to be a rate-limiting step for the ATPase cycle, whereas the potential for rate control of the cycle by modulation of the E2 to Ca2E1 transition is very small. Only in special circumstances (absence of potassium, high temperature, and using ITP as a substrate) did this transition become a rate-limiting step, subject to rate enhancement of the whole cycle by detergent perturbation.

[Effects of anti-infectious immunomodulators in leprosy and malaria in the mouse]. / Effets antiinfectieux d'immunomodulateurs dans la lèpre et la malaria, chez la souris.

Immunomodulators, whether natural (polysaccharides) or industrial (non-hemolytic detergents) proved active by themselves, in preventive or curative schemes of experimental leprosy and malaria. However, their activity was most often increased, through joint administration with chemotherapeutic agents.