Nickolay Koroukhov

A new double emulsion solvent diffusion technique for encapsulating hydrophilic molecules in PLGA nanoparticles

The commonly utilized techniques for encapsulating hydrophilic molecules in NP suffer from low encapsulation efficiency because of the drug rapid partitioning to the external aqueous phase. We hypothesized that combining the double emulsion system with a partially water-soluble organic solvent, could result in better encapsulation yield of hydrophilic molecules in nano-sized NP, and the utilization of both biocompatible surfactants and solvents. As a model drug we used alendronate, a hydrophilic low MW bisphosphonate. The new NP preparation technique, double emulsion solvent diffusion (DES-D), resulted in improved formulation characteristics including smaller size, lower size distribution, higher encapsulation yield, and more biocompatible ingredients in comparison to classical methods. The utilization of partially water-miscible organic solvent (ethyl acetate) enabled rapid diffusion through the aqueous phase forming smaller NP. In addition, the formulated alendronate NP exhibited profound inhibition of raw 264 macrophages, depletion of rabbits circulating monocytes, and inhibition of restenosis in the rat model. It is concluded that the new technique is advantageous in terms of smaller size, lower size distribution, higher encapsulation yield, and more biocompatible ingredients, with unaltered bioactivity.

Delivery of serotonin to the brain by monocytes following phagocytosis of liposomes

Many drugs are not able to enter the brain due to the presence of the blood-brain barrier (BBB) and therefore cannot be used in the treatment of diseases of the brain. Since it is now known that the brain is under immunological surveillance, we hypothesized that phagocytic cells of the innate immune system, mainly neutrophils and monocytes, can be exploited as transporters of drugs to the brain. To target circulating mononuclear phagocytic cells, negatively-charged nano-sized liposomes were formulated encapsulating serotonin, a BBB impermeable neurological drug. Brain uptake, biodistribution, and the mechanism of brain transport were examined in vitro and in rats and rabbits by utilizing double-radiolabeled (3)H (in the membrane) and (14)C-serotonin (in the core), and liposomes with fluorescent markers (membrane and core). The brain uptake of liposomal serotonin was significantly higher (0.138%+/-0.034 and 0.097%+/-0.011, vs. 0.068%+/-0.02 and 0.057%+/-0.01, 4 h and 24 h after IV administration in rats, serotonin liposomes and in solution, respectively). The same brain uptake of both empty and serotonin liposomes, the co-localization in the brain of both markers, and the unchanged ratio of (3)H:(14)C suggest that intact liposomes entered the brain. Since treatment of animals by liposomal alendronate resulted with inhibition of monocytes but not of neutrophils, and with no brain delivery, it is suggested that monocytes are the main transporters of liposomes to the brain.

Single and double emulsion manufacturing techniques of an amphiphilic drug in PLGA nanoparticles: formulations of mithramycin and bioactivity.

Formulation of hydrophilic compounds in nanoparticles is problematic due to their escape to the external aqueous phase. The certain amphiphilic nature of mithramycin, utilized clinically in cancer, makes its incorporation into nanoparticles an interesting challenge, elucidating the formulation factors of amphiphilics in nanoparticles. We hypothesized that mithramycin nanoparticles could provide more effective therapy of restenosis due to its antiproliferating and potential monocyte inhibition properties. The nanoprecipitation technique (designed for lipophilic compounds) was found preferable, with better encapsulation efficiency, than the emulsification solvent diffusion (ESD) technique (79.3 +/- 3.1% and 40.8 +/- 1.1%, respectively). The double emulsion solvent diffusion (DESD) method, designed for hydrophilic compounds, yielded similar encapsulation efficiency (80%). Nanoparticles size was, 110 +/- 36, 130 +/- 30, and 160 +/- 31 nm, ESD, nanoprecipitation, and DESD techniques, respectively. Mithramycin solution and in nanoparticles significantly inhibited RAW264 macrophages and smooth muscle cells in a dose-dependent relationship, and reduced the number of circulating monocytes in rabbits. However, no inhibition of restenosis was obtained in the rat carotid model following i.v. administration of mithramycin nanoparticles. It can be concluded that PLGA-based polymeric nanoparticles of mithramycin can be formulated by techniques suitable for lipophilic/hydrophilic compounds. The ineffectiveness in the rat restenosis model is probably due to the short depletion period of circulating monocytes and lack of arterial targeting.

Route of administration-dependent anti-inflammatory effect of liposomal alendronate

Innate immunity and inflammation are of major importance in various pathological conditions. Intravenous (IV) and intraperitoneal (IP) liposomal alendronate (LA) treatments have been shown to deplete circulating monocytes and peritoneal macrophages resulting in the inhibition of restenosis and endometriosis (EM), respectively. Nevertheless, the correlation between the extent of circulating monocyte depletion and liposome biodistribution is unknown, and the route of administration-dependent bioactivity in restenosis and EM has not been determined. We found that, LA treatment resulted in a dose-response modified biodistribution following both IV and IP administrations. The biodistribution of high-dose LA (10mg/kg), but not that of the low-dose (1mg/kg), was similar in healthy and diseased animals. It is concluded that LA impedes its own elimination from the circulation by depleting circulating monocytes and/or inhibiting their endocytic activity, in a dose-dependent manner. Both IV and IP administration of LA mediated by the partial and transient depletion of circulating monocytes effected inhibition of restenosis. Inhibition of EM was effected only by IP administration, which depleted both intraperitoneal and circulating monocytes. Thus, EM should be considered as a local inflammatory condition with systemic manifestations as opposed to restenosis, a systemic inflammatory disease.

Aspirin reduces the prothrombotic activity of C‐reactive protein

Summary.  Aim: C‐reactive protein (CRP) is a risk marker and a potential modulator of vascular disease. Previous studies support a prothrombotic activity of CRP, with impaired thromboregulation. The present study examined the antithrombotic effect of aspirin in mice transgenic for human CRP (CRPtg mice). Mechanistic investigations further elucidated the effect of CRP on prostanoid metabolism in vivo and in vitro. Methods and Results: Administration of aspirin (30 mg kg−1 day−1) to CRPtg mice slowed the accelerated thrombosis after photochemical injury to the carotid (99 ± 32 vs. 45 ± 24 min and 75 ± 23 vs. 82 ± 26 min in wild‐type mice vs. CRPtg mice, without and following aspirin treatment, respectively). Vascular injury modulated the expression of key pathways in prostanoid metabolism differently in CRPtg mice and wild‐type mice. Suppression of cyclo‐oxygenase 2 (COX‐2)‐derived metabolism with suppression of prostaglandin I2 (PGI2) synthase and PGI2 metabolism was recorded in the injured artery with increased thromboxane receptor expression. Aspirin therapy reduced the difference in PGI2 biosynthesis between CRPtg mice and wild‐type mice. In vitro studies in human‐derived cells further supported these findings. Incubation of human umbilical vein endothelial cells (HUVECs) with human recombinant CRP (5 μg mL−1) suppressed PGI2 synthase expression and significantly increased thromboxane receptor levels. Incubation of smooth muscle cells with CRP did not affect prostanoid expression. Conclusions: CRP modulates prostanoid metabolism to favor vascular occlusion. Elevated CRP levels might predispose to the cardiovascular hazard conferred by selective COX‐2 inhibitors, and the risk mediated by CRP may be limited by aspirin.

Additive-free albumin nanoparticles of alendronate for attenuating inflammation through monocyte inhibition.

AIMS Particulated dosage forms of bisphosphonates, such as polymeric nanoparticles and liposomes, deplete circulating monocytes and attenuate inflammation. The aim of this work was to develop a novel formulation of albumin nanoparticles with no crosslinkers that encapsulate the bisphosphonate, alendronate and, further, to examine its bioactivity in vitro and in vivo. RESULTS The novel formulation was prepared by desolvation of human serum albumin in acidic pH induced by alendronate, which enables an electrostatic interaction between albumin and the acidic drug. The mean particle size of the negatively charged nanoparticle was 250-300 nm and drug-entrapment efficiency was 49%. The formulation can be filter sterilized and lyophilized for increased stability. Alendronate nanoparticles exhibited significant inhibitory effects on RAW264 macrophage growth and a significant attenuation of stenosis in rats. CONCLUSION It is concluded that bioactive nanoparticles of human albumin can be formulated without crosslinkers and potentially toxic additives.

Biodistribution and imaging studies of 67Ga-labeled liposomes in rabbits with a vascular injury

Innate immunity and inflammation are of major importance in vascular repair. Monocytes and neutrophils adhesion and infiltration occur immediately after vascular injury. We hypothesized that the systemic inflammatory state following vascular injury would result in altered biodistribution of the administered liposomes. The purpose of this study was to assess the biodistribution of liposomes in intact and balloon-injured rabbit carotid arteries. Real-time imaging, single photon emission computed tomography (SPECT) and dynamic tomography were used to evaluate the dynamic biodistribution. In addition, γ-counter scintigraphy of organ explants was used. Increased accumulation of liposomes was observed in the liver and spleen. Furthermore, a significantly higher concentration of liposomes was observed in the injured carotid in comparison to the intact artery, 0.091 ± 0.040% and 0.033 ± 0.016%, 24 h post-injection, respectively. Our findings emphasize the importance of assessing the distribution of drug and liposomal formulations under pathological conditions which are associated with an inflammatory process.

Differentially Severe Cognitive Effects of Compromised Cerebral Blood Flow in Aged Mice: Association with Myelin Degradation and Microglia Activation

Bilateral common carotid artery stenosis (BCAS) models the effects of compromised cerebral blood flow on brain structure and function in mice. We compared the effects of BCAS in aged (21 month) and young adult (3 month) female mice, anticipating a differentially more severe effect in the older mice. Four weeks after surgery there was a significant age by time by treatment interaction on the radial-arm water maze (RAWM; p = 0.014): on the first day of the test, latencies of old mice were longer compared to the latencies of young adult mice, independent of BCAS. However, on the second day of the test, latencies of old BCAS mice were significantly longer than old control mice (p = 0.049), while latencies of old controls were similar to those of the young adult mice, indicating more severe impairment of hippocampal dependent learning and working memory by BCAS in the older mice. Fluorescence staining of myelin basic protein (MBP) showed that old age and BCAS both induced a significant decrease in fluorescence intensity. Evaluation of the number oligodendrocyte precursor cells demonstrated augmented myelin replacement in old BCAS mice (p < 0.05) compared with young adult BCAS and old control mice. While microglia morphology was assessed as normal in young adult control and young adult BCAS mice, microglia of old BCAS mice exhibited striking activation in the area of degraded myelin compared to young adult BCAS (p < 0.01) and old control mice (p < 0.05). These findings show a differentially more severe effect of cerebral hypoperfusion on cognitive function, myelin integrity and inflammatory processes in aged mice. Hypoperfusion may exacerbate degradation initiated by aging, which may induce more severe neuronal and cognitive phenotypes.