Fluorescent (rhodamine), folate decorated and doxorubicin charged, PEGylated nanoparticles synthesis

PEGylated silica nanoparticles, giving very stable aqueous sols, were successfully functionalised with rhodamine, one of the more stable fluorophore; they were also decorated with the targeting agent folic acid (FA) and charged with the well known drug doxorubicin. Rhodamine functionalization required a modification of the synthesis route of the nanoparticles (NP). Functionalization with FA required activation with 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide hydrochloride. Folate decorated NP were easily charged with doxorubicin. The experimental results proved the successfulness of the functionalization. The bond to the NP does not reduce the therapeutic efficacy of the drug. The calculated encapsulation efficiency (32 %) was only a little lower than the value (47 %) reported for the very popular PEGylated PLGA NP.

In vivo administration of fluorescent dextrans for the specific and sensitive localization of brain vascular pericytes and their characterization in normal and neurotoxin exposed brains

We have aimed to develop novel histochemical markers for the labeling of brain pericytes and characterize their morphology in the normal and the excitotoxin-exposed brain, as this class of cells has received little attention until recently. Pericyte labeling was accomplished by the intracerebroventricular injection of certain fluorescent dextran conjugates, such as Fluoro-Gold-dextran, FR-dextran, FITC-dextran and Fluoro-Turquoise (FT)-dextran. 1-7 days after the tracer injection, extensive labeling of vascular pericytes was seen throughout the entire brain. These cells were found distal to the endothelial cells and exhibited large dye containing vacuoles. The morphology of the pericytes was somewhat variable, exhibiting round or amoeboid shapes within larger intracellular vesicles, while those wrapping around capillaries exhibited a more elongated appearance with finger-like projections. The use of FG-dextran resulted in bluish yellow fluorescently labeled pericytes, while FR-dextran resulted in red fluorescent labeled pericytes, FITC-dextran exhibited green fluorescent pericytes and FT-dextran showed fluorescent blue pericytes in the brain. We have used these tracers to study possible changes in morphology and pericyte number following kainic acid insult, observing that the number of pericytes in the injured or lesioned areas of the brain is dramatically reduced compared to the non-injured areas. These novel fluorochromes should be of use for studies involving the detection and localization of pericytes in both normal and pathological brain tissues.

Synthesis of hierarchically nanoporous silica films for controlled drug loading and release

Films with well-controlled porous structures provide many exciting application opportunities in chemistry and biology. Here we report the synthesis of a highly uniform, hierarchically nanoporous silica film structure, and its application in drug loading and release for antibacterial surface coating. Templated by both sub-micron poly-styrene (PS) particles and a triblock copolymer (F127), this hierarchically nanoporous film has two distinct pore sizes of 200 nm and 7 nm. The 7-nm mesopores provide high surface area and thus high adsorption capacity for drug molecules, and the 200-nm macropores facilitate the adsorption rate of drug molecules, especially for molecules with comparable sizes to mesopores. Fluorescence measurement of rhodamine release demonstrates that this hierarchically porous film has a higher adsorption capacity, efficiency and much longer molecule releasing time window than both the inverse opal film and the mesoporous film. When loaded with Ampicillin, this hierarchically porous film shows over 8 times longer of inhibition of E. coli growth than both the inverse opal film and the mesoporous film. This simple and versatile process allows for fabrication of a variety of surface-coated, hierarchically nanoporous films with different chemical compositions and applications.

[Preparation of polyelectrolyte microcapsules containing ferrosoferric oxide nanoparticles]

In this study, polyelectrolyte microcapsules have been fabricated by biocompatible ferrosoferric oxide nanoparticles (Fe3O4 NPs) and poly allyamine hydrochloride (PAH) using layer by layer assembly technique. The Fe3O4 NPs were prepared by chemical co-precipitation, and characterized by transmission electron microscopy (TEM) and infrared spectrum (IR). Quartz cell also was used as a substrate for building multilayer films to evaluate the capability of forming planar film. The result showed that Fe3O4 NPs were selectively deposited on the surface of quartz cell. Microcapsules containing Fe3O4 NPs were fabricated by Fe3O4 NPs and PAH alternately self-assembly on calcium carbonate microparticles firstly, then 0.2 molL(-1) EDTA was used to remove the calcium carbonate. Scanning electron microscopy (SEM), Zetasizer and vibrating sample magnetometer (VSM) were used to characterize the microcapsule's morphology, size and magnetic properties. The result revealed that Fe3O4 NPs and PAH were successfully deposited on the surface of CaCO3 microparticles, the microcapsule manifested superparamagnetism, size and saturation magnetization were 4.9 +/- 1.2 microm and 8.94 emu x g(-1), respectively. As a model drug, Rhodamin B isothiocyanate labeled bovine serum albumin (RBITC-BSA) was encapsulated in microcapsule depended on pH sensitive of the microcapsule film. When pH 5.0, drug add in was 2 mg, the encapsulation efficiency was (86.08 +/- 3.36) % and the drug loading was 8.01 +/- 0.30 mg x m(L-1).

Development and characterization of oligonucleotide-tagged dye-encapsulating EPC/DPPG liposomes

Liposomes applications in health care include meanly their ability to carry drugs and genes inside the human body for therapeutic purposes. Nevertheless their applicability can extend far beyond and could be used as analytical tools in order to perform rapid, low-cost, sensitive and specific analyses. Their physical characteristics, such as large internal volume and extended surface area, render them ideal for these applications and specifically for improving the specificity and sensitivity of the analytical assay. The purpose of this study was to develop a simple, stable and low-cost oligonucleotide-tagged liposomal formulation consisting of EggPC and DPPG with a simple to synthesize thiol-reactive conjugate (Mal-SA) incorporated into the lipid bilayer of liposomes. The prepared liposomes, having also the water soluble dye Sulforhodamine B encapsulated in their inner cavity, were characterized in terms of their physicochemical (size, size distribution, zeta-potential, lipid content) and mechanical (morphology, rigidity) properties. The results showed that the final liposomal formulation could be used in the future as analytical tool for detecting pathogen strains of microorganism in biological milieu.

Evaluation of rhodamine B as an orally delivered biomarker for rodents and a feed-through transtadial biomarker for phlebotomine sand flies (Diptera: Psychodidae)

The purpose of this study was to evaluate the use of rhodamine B as an orally delivered biomarker for rodents and a feed-through transtadial biomarker for phlebotomine sand flies (Diptera: Psychodidae). Rhodamine B-treated hamsters were visibly marked for up to 8 wk, and their feces were fluorescent when examined under a fluorescence microscope. The development and survival of sand fly larvae fed feces of rhodamine B-treated hamsters were not significantly different from control sand flies. Adult male and female sand flies, that had been fed as larvae the feces of rhodamine B-treated hamsters, were fluorescent when examined using fluorescent microscopy and could be distinguished from control sand flies. Adult female sand flies that took bloodmeals from rhodamine B-treated hamsters were fluorescent when examined immediately after feeding. Rhodamine B incorporated rodent baits could be used to detect adult male and female sand flies that fed on the feces of baited rodents as larvae, or adult female sand flies that have taken a bloodmeal from bait-fed rodents. This would allow the delineation of specific foci with rodent-sand fly associations that would be susceptible to control by using feed-through or systemic insecticides.

Rhodamine-loaded poly(lactic-co-glycolic acid) nanoparticles for investigation of in vitro interactions with breast cancer cells

Nanoparticle-based drug delivery systems are considered promising for the delivery of imaging agents and drugs for the detection and treatment of illnesses, including cancer. Investigation of nanoparticle interactions with the diseased cells can lead to better designs. In this work, poly(lactic-co-glycolic acid) nanoparticles loaded with rhodamine 6G were prepared by nanoprecipitation with high encapsulation efficiency. In vitro release studies demonstrated that rhodamine escaped from the nanoparticles at a very slow rate at physiological pH, thus making it ideal for imaging studies. At acidic pH this agent was released quickly, suggesting charge interactions between the polymer and rhodamine. Microscopy and flow cytometry studies show higher uptake in MDA-MB-231 breast cancer cells when exposed to rhodamine-loaded nanoparticles than to rhodamine in solution.

In vivo staining of neocortical astrocytes via the cerebral microcirculation using sulforhodamine B

Staining and imaging glial cells in vivo while observing the microvasculature could help understand brain physiology, namely neuronal-glial-vascular communication. Two-photon excitation microscopy provides a means to monitor these interactions at the cellular level in living animals, but the cells of interest must be fluorescent. Injecting dyes intravenously is a rapid and quasi noninvasive method to stain cells in the brain. It necessitates that the dye is soluble in the blood plasma and crosses the blood brain barrier (BBB). We demonstrate here, using two-photon imaging, that sulforhodamine B (SRB) crosses the BBB and stains in vivo, specifically mouse astrocytes. This is confirmed by experiments on primary neurons and astrocytes cultures showing the preferential SRB staining of the latter. SRB is rapidly eliminated from the blood, which allows repeated injections in longitudinal studies.

Cytotoxic effects and in vitro reversal of multidrug resistance by therapeutic ultrasound in human hepatocarcinoma cell line (HepG2)

Multidrug resistance (MDR) is one of the major obstacles to successful chemotherapy of human malignancies. Although many strategies have been explored to overcome MDR, none of them have been proven to be clinically useful until now. The aim of this study was to investigate whether a novel therapeutic ultrasound (US) approach would have useful effects on the reversal of MDR in cancer cells. Wild-type and MDR phenotype (HepG2/ADM) cells of the human hepatocarcinoma cell line HepG2 were exposed to 0.8 MHz US at an intensity of 0.43 W/cm(2) for a 9s exposure (total energy density: 3.87 J/cm(2)). After US exposure, cell number and viability were counted immediately, and flow cytometry was performed to measure retention of rhodamine 123 and adriamycin in HepG2 and HepG2/MDR cells. Both cell lines were then incubated in suspension with adriamycin, vincristine, etoposide, cisplatin and 5-fluorouracil, respectively, and the MTT assay was used to determine cytotoxicity. The results showed that US exposure could significantly increase the uptake of Rh123 and ADM by HepG2/ADM tumor cells. The resistant index for the chemotherapeutic drugs was significantly lower in the US-exposed HepG2/ADM cells than in those not exposed to US. It was therefore concluded that US exposure could enhance the sensitivity of HepG2/ADM tumor cells to these chemotherapeutic agents, and the functional and structural changes induced by previous US exposure in MDR tumor cells may be responsible for it. However, further study is needed to investigate the mechanism behind US-mediated reversal of MDR.

Magnetic Targeting of Nanometric Magnetic Fluid–loaded Liposomes to Specific Brain Intravascular Areas: A Dynamic Imaging Study in Mice

PURPOSE

To prospectively determine, by using dynamic imaging, whether a magnet placed over a specific area of the mouse brain could target systemically administered rhodamine-labeled magnetic fluid-loaded liposomes (MFLs) to that brain region.

MATERIALS AND METHODS

Experiments were performed with a French Ministry of Agriculture permit and regional ethics committee authorization. In seven anesthetized C57BL/6 mice, a closed cranial window was implanted above the left parieto-occipital cortex. A laser-scanning confocal fluorescence microscope (LSCFM) was used to track the intravenously injected rhodamine-labeled MFLs within this cortical area, through the cranial window. The MFLs were video monitored for 2 minutes every 15 minutes for 1 hour after injection. A magnet was placed on the cranial window implanted in four mice, while no magnet was placed in three (control) mice. After dynamic in vivo imaging, static in vivo imaging was performed with a different LSCFM. Ex vivo fluorescence histologic analysis was then performed. Paired Student t testing was used to compare the cerebral blood flow and two-dimensional flow values before and 1 hour after MFL injection. For image analysis, intergroup comparisons were performed by using an independent t test.

RESULTS

In vivo video monitoring through the window revealed that the rhodamine-labeled MFLs accumulated in the mouse brain microvasculature exposed to the magnet-first within superficial brain venules and then within intracerebral venules-with no significant change in blood flow (P > .05). MFLs accumulated neither in the arterioles of the mice with a magnet nor in the arterioles of the control mice. Static in vivo imaging findings confirmed the microvascular localization of the rhodamine-labeled MFLs, and histologic findings specified their accumulation on the side of the magnet only.

CONCLUSION

Real-time in vivo imaging of rhodamine-labeled MFLs in the mouse brain cortex revealed that these nanosystems can be magnetically targeted, through microvessels, to selected brain areas.

Long-lasting systemic bait markers for Eurasian badgers

This study was carried out to assess whether Rhodamine B, ethyl-iophenoxic acid (EtIPA), and propyl-iophenoxic acid (PrIPA) can be used as long-lasting systemic bait markers for free-living badgers (Meles meles). Between June and November 2003, these chemicals were incorporated into bait distributed around badger setts. Serum, hair, and whiskers from individually marked badgers were collected in the following 4 to 24 wk. Rhodamine B was detectable as fluorescent bands up to 24 wk after ingestion of the bait. Individual badgers were found positive for EtIPA and PrIPA up to 20 wk and 18 wk after exposure, respectively. This study indicates that Rhodamine B, PrIPA, and EtIPA could be used as long-lasting markers for badgers.

Coating Formulations for Microneedles

PURPOSE

To develop a rational basis for designing coating solution formulations for uniform and thick coatings on microneedles and to identify coating strategies to form composite coatings, deliver liquid formulations, and control the mass deposited on microneedles.

MATERIALS AND METHODS

Microneedles were fabricated using laser-cutting and then dip-coated using different aqueous, organic solvent-based or molten liquid formulations. The mass of riboflavin (vitamin B(2)) coated onto microneedles was determined as a function of coating and microneedle parameters. Coated microneedles were also inserted into porcine cadaver skin to assess delivery efficacy.

RESULTS

Sharp-tipped microneedles, including pocketed microneedles, were fabricated. Excipients that reduced coating solution surface tension improved coating uniformity, while excipients that increased solution viscosity improved coating thickness. Evaluation of more than 20 different coating formulations using FDA approved excipients showed that hydrophilic and hydrophobic molecules could be uniformly coated onto microneedles. Model proteins were also uniformly coated on microneedles using the formulations identified in the study. Pocketed microneedles were selectively filled with solid or liquid formulations to deliver difficult-to-coat substances, and composite drug layers were formed for different release profiles. The mass of riboflavin coated onto microneedles increased with its concentration in the coating solution and the number of coating dips and microneedles in the array. Coatings rapidly dissolved in the skin without wiping off on the skin surface.

CONCLUSIONS

Microneedles and coating formulations can be designed to have a range of different properties to address different drug delivery scenarios.

Strategy for prevention of local recurrence of pancreatic cancer after pancreatectomy: antitumor effect of gemcitabine mixed with fibrin glue in an orthotopic nude mouse model

BACKGROUND

Pancreatic cancer frequently recurs after operative treatment, resulting in a poor prognosis. Inhibition of proliferation of residual cancer cells is important for improved survival of patients with pancreatic cancer. Fibrin glue (FG) is a biocompatible, adherent hemostat that can deliver high concentrations of anticancer drugs to residual cancer cells. The aim of this study was to evaluate the local antitumor effect of a mixture of gemcitabine (GEM) and FG on pancreatic cancer cells implanted orthotopically in nude mice.

METHODS

SUIT-2 human pancreatic cells were injected into the tail of the pancreas of nude mice. Seven days later, groups of mice were treated with 80 mg/kg GEM mixed with 0.5 mL fibrin glue (GEM + FG), 0.5 mL FG alone (FG), single intraperitoneal (i.p.) injection of 80 mg/kg GEM (GEM1), i.p. injection of 80 mg/kg GEM weekly for 3 weeks (GEM1,2,3), GEM + FG followed by weekly GEM injections for 2 weeks (GEM + FG + GEM2,3), or i.p. injection of PBS weekly for 3 weeks (controls).

RESULTS

Twenty-eight days after cell injections, tumor volumes of groups treated with GEM + FG + GEM2,3, GEM1,2,3, GEM + FG, GEM1, and FG were decreased by 84%, 70%, 62%, 37%, and 10%, respectively, compared to that of control mice. GEM + FG + GEM2,3 had the strongest anticancer effect compared to all other groups (P < .05). Additionally, GEM + FG showed a more potent antitumor effect compared to GEM1 (P < .05). Survival of mice treated with GEM + FG + GEM2,3 was longer than that of mice in all other groups (P < .05).

CONCLUSIONS

A mixture of GEM and FG was effective in inhibiting the growth of orthotopically implanted pancreatic neoplasms in nude mice. This procedure may be useful clinically to prevent the local recurrence of pancreatic cancer after pancreatectomy.

Mechanism of fluid infusion during microneedle insertion and retraction

Previous work has shown that infusion flow rates can be increased by an order of magnitude by partially retracting microneedles after insertion into the skin. This study sought to determine the mechanism by which retraction increases fluid infusion by piercing human cadaver skin with single microneedles, fixing the skin after retracting microneedles to different distances, and examining skin microstructure by histology. We found that microneedle insertion to 1080 microm from the skin surface resulted primarily in skin indentation and only 100-300 microm penetration into the skin. This caused significant compaction of the skin, which probably pressed out most water and thereby dramatically lowered the flow conductivity of skin beneath the needle tip. Retraction of the microneedle allowed the skin to recoil back toward its original position, which relieved the skin compaction and increased local flow conductivity. Altogether, these results suggest that microneedle insertion to penetrate into the skin followed by microneedle retraction to relieve skin compaction is an effective approach to infuse fluid into the skin in a minimally invasive manner.

Treatment of experimental autoimmune uveoretinitis with poly(lactic acid) nanoparticles encapsulating betamethasone phosphate

We have developed nanoparticles (NPs), which are capable of targeting a specific lesion and gradually releasing the agent at the site over a prolonged time period after a single intravenous administration. In this study, we evaluated the effects of intravenously administered poly(lactic acid) nanoparticles encapsulating betamethasone phosphate (BP-PLA NPs) on experimental autoimmune uveoretinitis (EAU) in Lewis rats. To determine the localization of NPs within the retina and choroid of rats with EAU, rhodamine (Rh)-encapsulated PLA NPs were injected intravenously and visualized by confocal microscopy. After the disease onset of EAU induced by S-antigen peptide in Lewis rats, either BP-PLA NPs, BP, or saline was injected intravenously, and the eyes were obtained 7 days following treatment and the histological score was determined. The clinical course of EAU was examined using pathological findings and the expression of the glial fibrillary acidic protein, rod opsin, and the surface markers of inflammatory cells (ED1 and pan T-cell) were immunohistochemically determined. Furthermore, T-cell proliferation and delayed-type hypersensitivity (DTH) to S-antigen were assessed. Intravenously injected Rh-PLA NPs accumulated in the retina and choroid of rats with EAU within 3 hr and remained over the succeeding 7-day-period. Furthermore, systemically administered BP-PLA NPs reduced the clinical scores of rats with EAU in 1 day, which were maintained for 2 weeks and decreased the histological scores. In addition, the ocular infiltration of activated T-cells and macrophages in addition to the hypertrophy of Müller cells were markedly reduced with this treatment. Meanwhile, T-cell proliferation and DTH of BP-PLA NPs-treated rats against S-antigen peptide were not significantly different from those of saline-treated rats. Systemically administered BP-PLA NPs inhibit the development of EAU due to the targeting and the sustained release of steroids in situ. The results of these studies suggest that the systemic administration of BP-PLA NPs may lead to a new therapeutic strategy in controlling intraocular inflammation.

Integrin-driven actin polymerization consolidates long-term potentiation

Long-term potentiation (LTP), like memory, becomes progressively more resistant to disruption with time after its formation. Here we show that threshold conditions for inducing LTP cause a rapid, long-lasting increase in polymerized filamentous actin in dendritic spines of adult hippocampus. Two independent manipulations that reverse LTP disrupted this effect when applied shortly after induction but not 30 min later. Function-blocking antibodies to beta1 family integrins selectively eliminated both actin polymerization and stabilization of LTP. We propose that the initial stages of consolidation involve integrin-driven events common to cells engaged in activities that require rapid morphological changes.

Drug delivery to the cochlea using PLGA nanoparticles

OBJECTIVES

This study aimed to investigate the efficacy of encapsulating therapeutic molecules in poly lactic/glycolic acid (PLGA) nanoparticles for drug delivery to the cochlea.

STUDY DESIGN

An experimental study.

METHODS

We examined the distribution of rhodamine, a fluorescent dye, in the cochlea, liver, and kidney of guinea pigs. Intravenous injection of rhodamine or rhodamine-encapsulated PLGA nanoparticles was used to target the fluorescent dye systemically to the liver, kidney, and cochlea, and these molecules were applied locally to the round window membrane (RWM) of the cochlea. The localization of rhodamine fluorescence in each region was quantitatively analyzed.

RESULTS

After systemic application of rhodamine nanoparticles, fluorescence was identified in the liver, kidney, and cochlea. The systemic application of nanoparticles had a significant effect on targeted and sustained delivery of rhodamine to the liver but not the kidney or cochlea. Rhodamine nanoparticles placed on the RWM were identified in the scala tympani as nanoparticles, indicating that the PLGA nanoparticles can permeate through the RWM. Furthermore, the local application of rhodamine nanoparticles to the RWM was more effective in targeted delivery to the cochlea than systemic application.

CONCLUSIONS

These findings indicate that PLGA nanoparticles can be an useful drug carrier to the cochlea via local application.

Enhanced adhesion of ligand‐conjugated biodegradable particles to colitic venules

The expression of certain endothelial cell adhesion molecules (ECAMs) is increased in the vasculature of the inflamed bowel (e.g., colitis), thereby providing an opportunity for targeted drug delivery. We recently demonstrated that biodegradable particles conjugated with ligands to ECAMs exhibit significant selective adhesion to ECAM expressing endothelium. In the present study, we used a murine model of colitis to determine whether poly(lactic acid)-poly(ethylene glycol) particles conjugated with a VCAM-1 ligand (alpha-V) exhibit enhanced adhesion to colitic vasculature. In post-capillary venules of the colon, significantly more alpha-V particles accumulate in colitic mice relative to (i) control mice (i.e., selectivity) and (ii) particles bearing a control ligand (i.e., ligand efficiency). The selectivity and ligand efficiency of alpha-V particles were a function of the total number of particles infused. The highest selectivity observed within our test regime was 3, while ligand efficiency increased linearly with the number of particles injected to a value of 24. This work represents a significant step towards achieving a targeted drug delivery scheme for the treatment of inflammatory bowel disease and indicates that the efficiency of targeting is dependent on the dose regime.

Investigation of fractions present in the stem bark of Annickia kummeriae on their P-glycoprotein inhibitory pump activity

Using MCF-7R cells and rhodamine 6G as the fluorescent probe, a bioassay-targeted purification process was pursued in order to isolate the active P-gp inhibitory fractions from Annickia kummeriae. Of 24 fractions obtained in the first preparative liquid chromatography (p-LC) run, only fraction 1 exhibited activity. Further p-LC fractionation led to the separation of fraction 1 into fractions 1.1-1.8. Fractions 1.4, 1.5 and 1.6 proved to be active by inducing a significant accumulation of rhodamine 6G by 3.3-, 4.5- and 4.9-fold at 10 microg/mL, and by 5.3-, 6.3- and 6.8-fold at 100 microg/mL, respectively. Fraction 1.6 was separated into several fractions by using an analytical liquid chromatography (a-LC) system. Fractions 1.6.18, 1.6.19 and 1.6.20 were active and they induced an accumulation of rhodamine 6G by 3.0-, 1.8- and 3.5-fold at 1x microg/mL and by 4.8-, 6.7- and 6.8-fold at 10x microg/mL, respectively. Afterwards, 28.3 mg of fraction 1.6 was processed by a-LC, and fractions 1.6.18, 1.6.19 and 1.6.20 were collected separately and dried. The amounts of materials recovered were 6.2, 7.4 and <1 mg, corresponding to 21.9%, 26.1% and <3.5% of fraction 1.6, respectively. From the total amount injected and the relative masses represented by these fractions, it can be calculated that the 1x microg/mL level corresponded to ca. 35, 42 and <5 microg/mL, respectively. Fluorescence microscopy revealed that incubation of the cells with rhodamine 6G alone did not show any fluorescence, whereas cells which were incubated in medium containing rhodamine 6G together with fraction 1.4, 1.6 or reserpine, clearly indicated accumulation of the dye intracellularly. This is an indication that the active compounds effected high intracellular fluorescence by inducing accumulation of the dye in the cells through inhibition of the P-gp pump.

Penetration into solid tumor tissue of fluorescent latex microspheres: a mimic of liposome particles

BACKGROUND

Using liposomes as a vehicle to transport anticancer drugs to cancer cells, to increase their effectiveness and decrease their toxicity, has been studied for many years. However, due to technical difficulties, the path of penetration for liposome particles into solid tumor tissue is still not clear.

MATERIALS AND METHODS

In this report, rhodamine-labeled fluorescent latex microspheres were used as a model of liposome particles, combined with fluorescent staining of blood vessel CD31 and tumor cell nuclei. The penetration of microspheres from blood vessels in L1210JF solid tumors of mice was observed. After fluorescent latex microspheres were injected into tail vein, tumor tissue samples were collected at various times and cryosections were then made for fluorescent staining.

RESULTS

Under fluorescence microscopy, the red fluorescent latex microspheres, the green fluorescent blood vessels and the blue tumor cells in the cancer tissue were seen clearly. The leaking of microspheres out from blood vessels was seen directly.

CONCLUSION

The results confirmed that the tiny particles can only leak out through the holes of the broken blood vessels and spread out through the space in between the cells of the solid tumor.

New approach to vascular injection in fresh cadaver dissection

Vascular injection techniques for anatomic studies are often complementary. Use of colored gelatinous mixtures with methylene blue provides precious data about descriptive anatomy by the contrast that it produces in the tissues. The introduction of radiopaque medium, such as lead oxide, into the gelatinous mixture can be used as a complement by means of x-ray examination, in order to facilitate and to reduce the time of investigation. Addition of rhodamine B to the radiopaque mixture keeps the advantages of the contrast medium, but also permits further dissection to demonstrate some details shown by prior x-ray examination. This article compares these different injection techniques in the study of the nasal vascular network. Moreover, it depicts a new injection approach that allows the investigation of vascular territories depending on thin caliber arteries by selective reinjection, defining microangiosomes. Each above-cited technique was used in ten facial territories of fresh cadavers. The patterns of the vessels shown by these techniques were identical, with a constant visualization of infra-millimetric arteries. However, selective reinjection was the only method that permitted characterization of the proper vascular territory of the lateral nasal artery.

KINETIC CHARACTERIZATION OF P-GLYCOPROTEIN-MEDIATED EFFLUX OF RHODAMINE 6G IN THE INTACT RABBIT LUNG

P-Glycoprotein (P-gp) is an ATP-dependent drug efflux transporter involved in multidrug resistance and drug disposition in many organ systems. A majority of P-gp substrates are lipophilic amine drugs which also exhibit rapid extensive accumulation in lung tissue. P-gp is expressed in lung tissue, and the very nature of this drug efflux mechanism suggests a moderating role in pulmonary drug disposition. Little is known about P-gp-mediated efflux out of lung tissue or its kinetic characteristics as they may relate to the impact of P-gp on pulmonary drug accumulation. The present study develops an experimental and kinetic model to characterize the kinetics of P-gp-mediated efflux of rhodamine 6G dye (R6G) out of the intact rabbit lung. The perfusate concentration of R6G with time during recirculation through an isolated perfused rabbit lung was measured, and 66.6 +/- 2.6% (S.E.) of the perfusate R6G was taken up by the lung. In the presence of P-gp inhibitors, R6G uptake increased significantly to 87.5 +/- 1.1% (P < 0.002), indicating a functional pulmonary P-gp efflux transporter. Fractional lung accumulation of R6G increased with increasing R6G perfusate concentration, a result consistent with saturation of an efflux transporter. A parsimonious three-compartment kinetic model of R6G pulmonary disposition was used to interpret data sets from experiments with different perfusion variables and to estimate parameters descriptive of the dominant kinetic processes involved in R6G pulmonary accumulation. The estimated value of the kinetic parameter, k(pgp), rate constant for P-gp-mediated R6G efflux, indicates that this transporter plays a significant role in moderating R6G pulmonary disposition.

Visualisation of the uptake of two model xenobiotics into bean leaves by confocal laser scanning microscopy: diffusion pathways and implication in phloem translocation

The diffusion of two fluorescent dyes, Oregon Green 488 (Oregon Green) and Rhodamine B into the leaves of broad bean (Vicia faba L) plants was studied to simulate the foliar uptake process of pesticides. The uptake rate of these model xenobiotics into bean foliage was measured using a standard leaf surface wash-off method. Diffusion into leaf tissues was visualised in vivo by confocal laser scanning microscopy (CLSM). The moderately lipophilic dye (Rhodamine B) showed faster uptake than the hydrophilic one (Oregon Green), despite the former being a larger molecule. While no distinct channels or domains for preferential entry of any of the dyes could be detected in the cuticle layer by CLSM, two different diffusion patterns were identified for the movement of these two dyes after traversing the cuticle. Upon desorption from the cuticle, Rhodamine B diffused extensively into the vacuole of the epidermal cells. Further transport of this dye from the epidermal cells to the mesophyll cells was not observed. In contrast, Oregon Green was found in the epidermal cell walls and cytoplasm, and was also present in the mesophyll cells. Examination of the petioles of the treated leaves revealed that, once absorbed, Oregon Green moved readily out of the treated leaf, whereas Rhodamine B did not show any phloem translocation. It is proposed that these two different diffusion characters may be responsible for the contrasting phloem mobility of the two xenobiotics. The results are discussed in relation to the current knowledge on the uptake, translocation and efficacy of pesticides as influenced by their properties.