Overcoming clofazimine intrinsic toxicity: statistical modelling and characterization of solid lipid nanoparticles.

The aim of this work was to develop solid lipid nanoparticles (SLNs) loaded with clofazimine (CLZ) (SLNs-CLZ) to overcome its intrinsic toxicity and low water solubility, for oral drug delivery. A Box-Behnken design was constructed to unravel the relations between the independent variables in the selected responses. The optimized SLNs-CLZ exhibited the following properties: particle size ca 230 nm, zeta potential of -34.28 mV, association efficiency of 72% and drug loading of 2.4%, which are suitable for oral delivery. Further characterization included Fourier transformed infrared spectroscopy that confirmed the presence of the drug and the absence of chemical interactions. By differential scanning calorimetry was verified the amorphous state of CLZ. The storage stability studies ensured the stability of the systems over a period of 12 weeks at 4°C. In vitro cytotoxicity studies evidenced no effect of both drug-loaded and unloaded SLNs on MKN-28 gastric cells and on intestinal cells, namely Caco-2 and HT29-MTX cells up to 25 µg ml-1 in CLZ. Free CLZ solutions exhibited IC50 values of 16 and 20 µg ml-1 for Caco-2 and HT29-MTX cells, respectively. It can be concluded that the optimized system, designed considering important variables for the formulation of poorly soluble drugs, represents a promising platform for oral CLZ delivery.

Effect of Mycobacterium leprae lipids on BCG- and carrageenan-induced cellular recruitment in mouse pleurisy.

Pathogenic mycobacteria survive inside macrophages and deactivate these cells, using a mechanism that is still poorly understood. Mycobacterial cell wall lipids constitute the first contact with the host cell. Although Mycobaterium leprae and M. bovis BCG share common antigens, they induce opposite inflammatory responses. Apolar M. leprae lipids have been shown to be anti-inflammatory by down-regulating macrophage activation and T-cell functions. We wonder if these lipids would influence cellular migration to BCG or to other inflammatory agent. We investigated the effect of M. leprae, its lipids or delipidated bacteria on acute and chronic BCG- or carrageenan-induced pleurisy. Previous injection of intact or delipidated M. leprae did not alter either the BCG- or carrageenan-induced pleural inflammatory reaction. However, M. leprae lipids enhanced carrageenan-induced acute cellular migration without impairing BCG inflow; moreover, they reduced BCG chronic response. Together these data suggest distinct mechanisms for intracellular deactivation and pleural cell recruitment exerted by mycobacterial structures.

Down-regulatory effect of Mycobacterium leprae cell wall lipids on phagocytosis, oxidative respiratory burst and tumour cell killing by mouse bone marrow derived macrophages.

The authors have previously demonstrated that lipids from Mycobacterium leprae cell walls inhibit macrophage functions and are endowed with anti-inflammatory properties in vivo. To investigate these observations further, the authors describe here the influence of dead M. leprae or of the lipids extracted from the cell wall of the mycobacterium, enclosed in liposomes, on the phagocytic, oxidative respiratory burst and tumouricidal ability of bone marrow derived macrophages in vitro. Dead M. leprae or its cell wall lipids abrogated the oxidative respiratory burst and phagocytic ability of mouse bone marrow derived macrophages. A dose-dependent inhibitory effect of the bacterial lipid extract on tumour cell killing by lipopolysaccharide (LPS)-activated bone marrow derived macrophages was demonstrated. However, when delipidated M. leprae was added to cultures of bone marrow derived macrophages, immune phagocytosis and superoxide production was up-regulated. Mycobacterium leprae or its lipids did not appear to be toxic to those cells assayed by the MTT (methyl thiazol tetrazolium) test. These data, added to our preceding observations, support the hypothesis that the down-regulatory activity of M. leprae wall lipids on macrophage function might be one of the evasive mechanisms of the bacterium to enable it to perpetuate itself in the host tissues.

Dharmendra antigen but not integral M. leprae is an efficient inducer of immunostimulant cytokine production by human monocytes, and M. leprae lipids inhibit the cytokine production.

Killed integral Mycobacterium leprae, Mitsuda antigen, and chloroform-treated M. leprae, Dharmendra antigen (Dh-Ag), have been used for the classification of leprosy patients based on cell-mediated immunity. Heat-killed M. leprae also were used as a component of the Convit vaccine. Human blood monocytes were stimulated with M. leprae or Dh-Ag and their cytokine-inducing ability was compared. Monocytes were cultured in the presence of fresh human serum because of the efficiency of cytokine induction and the phagocytosis of M. leprae have been shown to be optimal in the presence of fresh serum. M. leprae and Dh-Ag were equally phagocytosed by monocytes. Dh-Ag was more potent than M. leprae in the induction of immunostimulatory/proinflammatory cytokines, interleukin-1 (IL-1), IL-6 and tumor necrosis factor (TNF). In contrast, a comparable level of IL-1ra, an immunosuppressive cytokine, was induced by M. leprae and Dh-Ag. The lipids extracted from M. leprae induced none of these cytokines by monocytes. Nevertheless, when monocytes were pretreated with the lipids followed by stimulation with Dh-Ag, productions of IL-1, IL-6 and TNF were all inhibited in a dose-dependent manner. However, the lipids did not inhibit the cytokine production induced by other stimuli including BCG and lipopolysaccharide. Moreover the lipids did not affect the production of IL-1ra. These results suggest that the lipids from M. leprae are responsible for the poor cytokine-inducing ability of M. leprae, thus favoring their infection. These results also suggest that Dh-Ag rather than integral M. leprae may be useful as a vaccine candidate because Dh-Ag is able to induce a large amount of cytokines from monocytes.

Lipids from Mycobacterium leprae cell wall are endowed with an anti-inflammatory property and inhibit macrophage function in vivo.

In general, the majority of bacteria are pre-inflammatory when injected in experimental animals. However, Mycobacterium leprae has no inflammatory effect when injected into mouse footpad, but using the delipidated mycobacteria we observed a mild significant increase in footpad oedema. Other mycobacteria, Mycobacterium bovis-BCG or M. tuberculosis induce a strong paw oedema. Furthermore, M. leprae reduced locally the BCG-induced inflammatory reaction in mouse footpad, whereas delipidated M. leprae did not influence this reaction. Both M. leprae and M. leprae cell wall lipids blocked immune phagocytosis in vivo by inflammatory macrophages (from an induced focus). In contrast delipidated M. leprae stimulated the phagocytosis reaction. Neither intact M. leprae. delipidated M. leprae, nor its lipids had any toxic effect on macrophages or on cell migration. Although M. leprae did not interfere on cell influx and cell type in an induced-inflammatory site, this mycobacterium led to the appearance of a distinct cell population in vivo. The hypothesis is that M. leprae would transform macrophages in epithelioid cells, suggested by morphology analysis of cells by fluorescence-activated cell sorter and observed under optic microscopy.

The effect of dioxyphenylalanine (DOPA), amides and some potential sources of energy on the multiplication of Mycobacterium leprae.

The multiplication of 2 out of 3 M. leprae strains on a medium containing substances from digested non-acid-fast microorganisms or even free of them was significally promoted to D-3,4-dihydroxyphenylalanine (DOPA). The following organic substances exerted growth-promoting effects on several strains: 0.02-0.10% concentrations of succinate greater than fumarate greater than alpha-ketoglutarate and acetate greater than glycerol; 0.2% concentrations of citrate and pyruvate greater than isonicotinamide and benzamide greater than lecithin. 0.5% concentrations of oleate greater than citrate greater than pyruvate greater than acetate greater than fumarate greater than succinate; 5.0% concentrations of butanol and butandiol greater than propanol greater than sorbitol greater than ethanol. However, these effects were variable and strains of various origins acted differently. On media containing DOPA, malachite-green (MG) and at least 0.12 x 10(6) microorganisms/ml the following oxidation-reduction reaction was observed: DOPA was oxidized to a brown compound and malachite-green reduced to an almost colourless product. Consequently, the blue-colour of the cultures turned from blue to brown. This DOPA-MG reaction and the inability to grow on conventional media were used for the identification of 10 cultures (inocula directly from patients) as M. leprae, while a DOPA-MG negative patient-strain grew on media employed for cultivable mycobacteria and was not identical with M. leprae, as proved by the foot-pad test in mice.