Pharmacokinetics, tissue distribution and immunomodulatory effect of intralipid formulation of nystatin in mice.

OBJECTIVES: We developed a novel lipid formulation of nystatin suitable for parenteral administration, nystatin-intralipid (NYT-IL), with antifungal activity and reduced toxicity in mice. We investigated the pharmacokinetics, tissue distribution and immunomodulatory effect of NYT-IL in mice. METHODS: Nystatin levels in serum and organs were determined using HPLC after NYT-IL or nystatin administration in mice. The levels of the pro-inflammatory cytokines tumour necrosis factor-α (TNF-α) and interferon-γ (IFN-γ) and the anti-inflammatory cytokine interleukin 10 (IL-10) produced by splenocytes from mice injected with NYT-IL or nystatin were evaluated by an ELISA assay. RESULTS: Injection of NYT-IL resulted in similar levels and similar kinetics of nystatin in serum, higher concentrations in the liver and lower concentrations in the kidneys, in comparison with nystatin injection. Injection of mice with NYT-IL yielded higher levels of IL-10 than that of nystatin, whereas the levels of TNF-α and IFN-γ induced by NYT-IL were lower than those elicited by nystatin. CONCLUSIONS: Since polyene treatment is associated with nephrotoxicity, lower levels of nystatin in the kidneys following NYT-IL injection suggest the possibility of reduced toxicity. As the acute infusion-related adverse effects associated with polyene treatment are considered to be induced by pro-inflammatory cytokines, a higher level of anti-inflammatory and lower levels of pro-inflammatory cytokines elicited by NYT-IL administration suggest the possibility of amelioration of such effects. In summary, the altered pharmacokinetics, tissue distribution and immune response due to the use of this intralipid formulation of nystatin merit further research towards the development of a therapeutic agent against invasive mycoses.

Cholesterol sequestration by nystatin enhances the uptake and activity of endostatin in endothelium via regulating distinct endocytic pathways.

Specific internalization of endostatin into endothelial cells has been proved to be important for its biologic functions. However, the mechanism of endostatin internalization still remains elusive. In this study, we report for the first time that both caveolae/lipid rafts and clathrin-coated pits are involved in endostatin internalization. Inhibition of either the caveolae pathway or the clathrin pathway with the use of chemical inhibitors, small interfering RNAs, or dominant-negative mutants alters endostatin internalization in vitro. Intriguingly, cholesterol sequestration by nystatin, a polyene antifungal drug, significantly enhances endostatin uptake by endothelial cells through switching endostatin internalization predominantly to the clathrin-mediated pathway. Nystatin-enhanced internalization of endostatin also increases its inhibitory effects on endothelial cell tube formation and migration. More importantly, combined treatment with nystatin and endostatin selectively enhances endostatin uptake and biodistribution in tumor blood vessels and tumor tissues but not in normal tissues of tumor-bearing mice, ultimately resulting in elevated antiangiogenic and antitumor efficacies of endostatin in vivo. Taken together, our data show a novel mechanism of endostatin internalization and support the potential application of enhancing the uptake and therapeutic efficacy of endostatin via regulating distinct endocytic pathways with cholesterol-sequestering agents.

[Intestinal candidiasis: modern therapeutic tactics].

Bowels candidiasis is an urgent problem not only for gastroenterology but also for other fields of medicine--gynecology, dentistry, phthisiology, surgery, etc. as this disease is directly related with the manifestations of systemic candidiasis in other organs. The diagnostics algorithm includes the detection of a filamentary form (pseudomyceliums) of micromycetes of the Candida genus in the morphological study of a tissue sampling of the bowels mucous coat. The drug of choice for the treatment of bowels candidiasis is Pimafucin (Natamycin) having a local action on the Candida fungi in the intestinal lumen in the absence of any systemic absorption of the drug or any side effects.

Chitosan delivery systems for the treatment of oral mucositis: in vitro and in vivo studies.

Oral mucositis is a frequent and potentially severe complication of radiation or chemotherapy for cancer. Associated with atrophy and ulceration of the oral mucosa is an increased risk of infection, and the most common pathogenic agent is Candida. Chitosan is an excellent candidate for the treatment of oral mucositis. Its bioadhesive and antimicrobial properties offer the palliative effects of an occlusive dressing and the potential for delivering drugs, including anti-candidal agents. The aim of this study was to develop an occlusive bioadhesive system for prophylaxis and/or treatment of oral mucositis. Gel and film formulations were prepared using chitosans at different molecular weights and in different solvents. Nystatin, which is considered as a prophylactic agent for oral mucositis was incorporated into the formulations. The in vitro release of nystatin from the formulations was decreased with the increasing molecular weight of chitosan. The effect of the formulations was investigated in vivo in hamsters with chemotherapy-induced mucositis. Mucositis scores in groups treated with nystatin incorporated into gel and suspension formulations were significantly lower (p < 0.05) than those treated with the chitosan gel alone. Survival of animals in the treated groups was higher than that in the control group. The retention time and distribution of the gels in the oral cavity were investigated in healthy volunteers. A faster distribution of nystatin in the oral cavity was obtained using the suspension compared to the gels, but the nystatin saliva level decreased rapidly as well. A drug concentration above the minimum inhibitory concentration (MIC) value for Candida albicans (0.14 microg/ml) was maintained for longer periods of time at the application site (90 min) than at the contralateral site (45 min) in the oral cavity.

Diversity of lipid-based polyene formulations and their behavior in biological systems.

Patients with cancer and infectious disease often display dyslipidemias that result in changes in their plasma lipoprotein-lipid composition. It is likely that the interactions of liposomal polyenes with plasma lipoproteins may be responsible for the far different pharmacokinetics and pharmacodynamics of these compounds when they are administered to infected patients rather than to animals or healthy volunteers. Amphotericin B (AmpB) and nystatin are examples of such polyenes. Amphotericin B initially distributes with the high-density lipoprotein (HDL) fraction upon incubation in plasma. Over time, AmpB redistributes from HDLs to low-density lipoproteins (LDLs). This redistribution appears to be regulated by lipid transfer protein. However, when AmpB is incorporated into liposomes composed of negatively or positively charged phospholipids, not only is the capability of LTP to transfer AmpB from HDL to LDL diminished, but AmpB remains retained with only the HDL fraction. However, when liposomal nystatin is incubated in plasma, over 50% of nystatin distributes with HDLs. Over time, nystatin redistributes from HDL to the lipoprotein-deficient plasma fraction, which is composed of mainly aqueous plasma proteins. The lipid composition selected for the drug appears to be a vital constituent in regulating the drug's interaction with biological fluids. Furthermore, liposome (or liposomal particle) size, fluidity, and other physiochemical characteristics also play a role in altering the pharmacokinetics and pharmacological effects of lipid-based drug formulations. Armed with this understanding, a rational approach to clinical development of these formulations could be facilitated.