Drug delivery in pluronic micelles: effect of high-frequency ultrasound on drug release from micelles and intracellular uptake.

The effect of high-frequency ultrasound on doxorubicin (DOX) release from Pluronic micelles and intracellular DOX uptake was studied for promyelocytic leukemia HL-60 cells, ovarian carcinoma drug-sensitive and multidrug-resistant (MDR) cells (A2780 and A2780/ADR, respectively), and breast cancer MCF-7 cells. Cavitation events initiated by high-frequency ultrasound were recorded by radical trapping. The onset of transient cavitation and DOX release from micelles were observed at much higher power densities than at low-frequency ultrasound (20-100 kHz). Even a short (15-30 s) exposure to high-frequency ultrasound significantly enhanced the intracellular DOX uptake from PBS, RPMI 1640, and Pluronic micelles. The mechanisms of the observed effects are discussed.     

Mechanism of the ultrasonic activation of micellar drug delivery.

The mechanism of the ultrasonic enhancement of the uptake of cytotoxic drugs, doxorubicin (DOX) and ruboxyl (Rb) by HL-60 cells from Pluronic micelles was studied. DOX and Rb sorption from either PBS or micellar Pluronic solutions is described by Langmuir-type isotherms characteristic of substrates with limited number of sorption centers. The sorption limits for Rb from PBS and Pluronic were considerably higher than those for DOX, presumably due to much higher Rb partitioning into cell membranes. The overall number of drug sorption centers for both drugs decreased in the presence of Pluronic implying the effect of Pluronic on the DNA conformation, which was confirmed by the electron paramagnetic resonance (EPR) experiments using Rb as a spin probe. Ultrasound increased drug uptake by the cells from PBS and Pluronic solutions. The fluorescence microscopy and flow cytometry experiments using fluorescently-labeled Pluronic showed that ultrasound enhanced both the intracellular uptake of Pluronic micelles and Pluronic trafficking into cell nuclei. A scheme is suggested that describes various equilibria controlling drug/cell interactions and effect of ultrasound on these equilibria. Under the action of ultrasound, the equilibrium between the micellar-encapsulated and free drug is shifted in the direction of free drug due to micelle perturbation; the equilibrium between extracellular and internalized drug is shifted to the intracellular drug due to the ultrasound-induced cellular changes that enhance the accessibility of various cellular structures to drug. An important advantage offered by ultrasound is that the same degree of the intracellular drug uptake may be achieved at a substantially lower drug concentration in the incubation medium.     

Acoustic activation of drug delivery from polymeric micelles: effect of pulsed ultrasound.

The effect of a continuous wave (CW) and pulsed 20-kHz ultrasound on the Doxorubicin (DOX) uptake by HL-60 cells from the phosphate buffered saline solution (PBS) and Pluronic micellar solutions was studied. Both CW and pulsed ultrasound enhanced DOX uptake from PBS and Pluronic micelles. The main factor that effected drug uptake was ultrasound power density; however, with increasing power, the enhanced drug uptake was accompanied by the extensive cell sonolysis. For PBS, no significant effect of duration of the ultrasound pulse or inter-pulse interval on the drug uptake was observed. For Pluronic micelles, the uptake increased with increasing pulse duration in the range 0.1-2 s, overall sonication time being the same. For 2-s pulses, the uptake was close to that under CW ultrasound. There was no significant effect of the duration of the inter-pulse interval on the drug uptake from Pluronic micelles. The data on the effect of pulse duration on drug uptake suggest that the characteristic times of drug release from micelles and drug uptake by the cells are comparable. The results point to two independent mechanisms controlling acoustic activation of drug uptake from Pluronic micelles. Both mechanisms work in concert. The first one is related to the acoustically-triggered drug release from micelles that results in higher concentration of the free drug in the incubation medium. The second mechanism is based on the perturbation of cell membranes that results in the increased uptake of the micellar-encapsulated drug. The intracellular uptake of Pluronic micelles was confirmed by fluorescence microscopy.     

Micellar delivery of doxorubicin and its paramagnetic analog, ruboxyl, to HL-60 cells: effect of micelle structure and ultrasound on the intracellular drug uptake.

The effect of Pluronic P-105 micelle structure and ultrasound on the uptake of two anthracycline drugs, doxorubicin and its paramagnetic analogue, ruboxyl, by HL-60 cells was investigated. Pluronic micellization was studied over the temperature range of 25-42 degrees C using the EPR and fluorescence spectroscopy. In the presence of Pluronic P-105 at concentrations corresponding to unimers (or loose aggregates), drug uptake by HL-60 cells was enhanced, apparently due to the effect of the polymeric surfactant on cell membrane permeability. At Pluronic concentrations corresponding to the formation of dense micelles with hydrophobic cores, drug uptake was substantially decreased. However, insonation with 70 kHz ultrasound enhanced the intracellular uptake of drugs encapsulated in dense Pluronic micelles. These findings may provide for developing a new technique of drug targeting by encapsulating the drug in micelles to prevent unwanted interactions with healthy cells and focusing ultrasound on a tumor to enhance drug uptake at the tumor site.     

Factors affecting acoustically triggered release of drugs from polymeric micelles.

A custom ultrasonic exposure chamber with real-time fluorescence detection was used to measure acoustically-triggered drug release from Pluronic P-105 micelles under continuous wave (CW) or pulsed ultrasound in the frequency range of 20 to 90 kHz. The measurements were based on the decrease in fluorescence intensity when drug was transferred from the micelle core to the aqueous environment. Two fluorescent drugs were used: doxorubicin (DOX) and its paramagnetic analogue, ruboxyl (Rb). Pluronic P-105 at various concentrations in aqueous solutions was used as a micelle-forming polymer. Drug release was most efficient at 20-kHz ultrasound and dropped with increasing ultrasonic frequency despite much higher power densities. These data suggest an important role of transient cavitation in drug release. The release of DOX was higher than that of Rb due to stronger interaction and deeper insertion of Rb into the core of the micelles. Drug release was higher at lower Pluronic concentrations, which presumably resulted from higher local drug concentrations in the core of Pluronic micelles when the number of micelles was low. At constant frequency, drug release increased with increasing power density. At constant power density and for pulse duration longer than 0.1 s, peak release under pulsed ultrasound was the same as stationary release under CW ultrasound. Released drug was quickly re-encapsulated between the pulses of ultrasound, which suggests that upon leaving the sonicated volume, the non-extravasated and non-internalized drug would circulate in the encapsulated form, thus preventing unwanted drug interactions with normal tissues.     

Enhanced intracellular delivery and improved antitumor efficacy of doxorubicin by sterically stabilized liposomes modified with a synthetic RGD mimetic.

While sterically stabilized liposomes (SSL) can passively accumulate into tumor tissue due to the effect of enhanced permeability and retention (EPR), the intracellular uptake of the entrapped anticancer drugs by the tumor cells should be a determinant step for their antitumor activities. Therefore, strategies that can enhance the intracellular uptake of SSL into tumor cells could lead to an improved therapeutic efficacy for the drugs. To check this possibility, RGD-mimetic-modified SSL (RGDm-SSL) were constructed aimed to achieve tumor accumulation as well as enhanced intracellular delivery, and were loaded with doxorubicin (DOX), an anticancer drug. Flow cytometry and confocal microscopy reveal that RGDm-SSL facilitated the DOX uptake into the melanoma cells via integrin-mediated endocytosis. DOX-loaded RGDm-SSL (RGDm-SSL-DOX) displayed higher cytotoxicity on melanoma cells than DOX-loaded SSL (SSL-DOX). Tissue distribution and therapeutic experiments were examined in C57BL/6 mice carrying melanoma B16 tumors. RGDm-SSL-DOX displayed similar DOX accumulation in tumor tissue to that of SSL-DOX but showed significantly lower DOX level in blood and remarkably higher DOX level in spleen than SSL-DOX. Administration of RGDm-SSL-DOX at a dose of 5 mg DOX/kg resulted in effective retardation of tumor growth and prolonged survival times compared with SSL-DOX. These results suggest that RGDm-modified SSL may be a promising intracellular targeting carrier for efficient delivery of chemotherapeutic agents into tumor cells.     

Doxorubicin-loaded poly(ethylene glycol)-poly(beta-benzyl-L-aspartate) copolymer micelles: their pharmaceutical characteristics and biological significance.

Doxorubicin (DOX) was physically loaded into micelles prepared from poly(ethylene glycol)-poly(beta-benzyl-L-aspartate) block copolymer (PEG-PBLA) by an o/w emulsion method with a substantial drug loading level (15 to 20 w/w%). DOX-loaded micelles were narrowly distributed in size with diameters of approximately 50-70 nm. Dimer derivatives of DOX as well as DOX itself were revealed to be entrapped in the micelle, the former seems to improve micelle stability due to its low water solubility and possible interaction with benzyl residues of PBLA segments through pi-pi stacking. Release of DOX compounds from the micelles proceeded in two stages: an initial rapid release was followed by a stage of slow and long-lasting release of DOX. Acceleration of DOX release can be obtained by lowering the surrounding pH from 7.4 to 5.0, suggesting a pH-sensitive release of DOX from the micelles. A remarkable improvement in blood circulation of DOX was achieved by use of PEG-PBLA micelle as a carrier presumably due to the reduced reticuloendothelial system uptake of the micelles through a steric stabilization mechanism. Finally, DOX loaded in the micelle showed a considerably higher antitumor activity compared to free DOX against mouse C26 tumor by i.v. injection, indicating a promising feature for PEG-PBLA micelle as a long-circulating carrier system useful in modulated drug delivery.     

Drug delivery in polymeric micelles: from in vitro to in vivo.

A new drug delivery modality was developed based on drug encapsulation in polymeric micelles followed by a controlled release at the tumor site triggered by ultrasound focused on the tumor. Ultrasound not only released drug from micelles but also enhanced the local uptake of both free and encapsulated drug by tumor cells, thus providing effective drug targeting. The significant success of in vitro studies of this new drug delivery technique warranted extending studies to animal experiments. Here the results of the in vitro studies of the above technique are summarized and the first in vivo experiments using colon cancer model in rats are reported. The in vivo results showed that application of low-frequency ultrasound (20 and 70 kHz) significantly reduced the tumor size when compared with non-insonated controls; this result indicated in vivo drug targeting to tumors by ultrasound.     

Doxorubicin loaded pH-sensitive polymeric micelles for reversal of resistant MCF-7 tumor.

In order to overcome multidrug resistance in solid tumors, doxorubicin (DOX) loaded pH-sensitive micelles of which surface was decorated with folate (PHSM/f) were evaluated both in vitro and in vivo experiments. PHSM/f were fabricated from a mixture of two block copolymers of poly(L-histidine) (M(n): 5K)-b-PEG (M(n): 2K)-folate (polyHis/PEG-folate) (75 wt.%) and poly(L-lactic acid) (M(n): 3K)-b-PEG (M(n): 2K)-folate (PLLA/PEG-folate) (25 wt.%). The PHSM/f showed more than 90% cytotoxicity of DOX resistant MCF-7 (MCF-7/DOX(R)) when cultured with PHSM/f at a concentration of 10 microg/ml DOX. The result was interpreted by a sequential event of active internalization of PHSM/f via folate-receptor mediated endocytosis and ionization of His residues which result in micelle destabilization and probably disturbance of endosomal membranes. This potential mechanism may endow the drug carriers to bypass Pgp efflux pump and sequestration of DOX in acidic intracellular compartments, yielding high cytotyoxicity. Experimental evaluation of tumor regression was carried out in a small animal model bearing s.c. MCF-7 or MCF-7/DOX(R) xenografts. The tumor (MCF-7/DOX) volumes of mice treated with PHSM/f were significantly less than control groups treated with free DOX or similar micelles but without folate (PHSM). In the MCF-7/DOX(R) xenograft model, the accumulated DOX level of PHSM/f in solid tumors was 20 times higher than free DOX group, and 3 times higher than PHSM group. The results demonstrate that PHSM/f is a viable means for treating drug resistant tumors.     

Reduction responsive and surface charge switchable polyurethane micelles with acid cleavable crosslinks for intracellular drug delivery

Previously we synthesized redox sensitive polyurethane micelles, core crosslinked by diisocyanates (PU-CCL). To improve the intracellular drug release and tumor cellular toxicity of anticancer drugs loaded into polyurethane micelles, we now describe redox sensitive polyurethane micelles with tunable surface charge switchabilities, crosslinked with pH cleavable Schiff bonds, as anticancer drug carriers. Different amounts of 1,6-diaminohexane were connected onto the pendant carboxyl groups of amphiphilic multi-blocked polyurethane (PU-SS-COOH), resulting in polyurethanes with various ratios of pendant carboxyl and amine groups (denoted as PU-SS-COOH-NH₂-1, PU-SS-COOH-NH₂-2 and PU-SS-COOH-NH₂-3). The surface charge switched as the pH was increased for PU-SS-COOH-NH₂-1, PU-SS-COOH-NH₂-2 and PU-SS-COOH-NH₂-3. Then the PU-SS-COOH-NH₂-3 micelles, dissolved in water, were crosslinked by glutaraldehyde resulting in surface charge switchable and reduction responsive polyurethane micelles with acid cleavable crosslinks (PU-ACCL). The crosslinked polyurethane micelles (PU-ACCL) demonstrated superior particle stability in phosphate buffered saline (PBS, pH = 7.4) solution without reducing agents, whereas the drug release rate was markedly accelerated by the addition of glutathione (GSH). Notably, the drug release from PU-ACCL was further accelerated in acidic fluid as the result of acid induced cleavage of the crosslinks. In vitro cytotoxicity studies demonstrated that doxorubicin (DOX)-loaded PU-ACCL micelles displayed increased cytotoxicity against tumor cells which was comparable to that obtained for DOX loaded into uncrosslinked polyurethane micelles. The reduction responsive and surface charge switchable polyurethane micelles with acid cleavable crosslinks, which have superior extracellular stability and provide rapid intracellular drug release, may hold great potential as a bio-triggered drug delivery system for cancer therapy.

Previously we synthesized redox sensitive polyurethane micelles, core crosslinked by diisocyanates (PU-CCL).     

Design and Evaluation of Doxorubicin-containing Microbubbles for Ultrasound-triggered Doxorubicin Delivery: Cytotoxicity and Mechanisms Involved

Drug delivery with microbubbles and ultrasound is gaining more and more attention in the drug delivery field due to its noninvasiveness, local applicability, and proven safety in ultrasonic imaging techniques. In this article, we tried to improve the cytotoxicity of doxorubicin (DOX)-containing liposomes by preparing DOX-liposome-containing microbubbles for drug delivery with therapeutic ultrasound. In this way, the DOX release and uptake can be restricted to ultrasound-treated areas. Compared to DOX-liposomes, DOX-loaded microbubbles killed at least two times more melanoma cells after exposure to ultrasound. After treatment of the melanoma cells with DOX-liposome-loaded microbubbles and ultrasound, DOX was mainly present in the nuclei of the cancer cells, whereas it was mainly detected in the cytoplasm of cells treated with DOX-liposomes. Exposure of cells to DOX-liposome-loaded microbubbles and ultrasound caused an almost instantaneous cellular entry of the DOX. At least two mechanisms were identified that explain the fast uptake of DOX and the superior cell killing of DOX-liposome-loaded microbubbles and ultrasound. First, exposure of DOX-liposome-loaded microbubbles to ultrasound results in the release of free DOX that is more cytotoxic than DOX-liposomes. Second, the cellular entry of the released DOX is facilitated due to sonoporation of the cell membranes. The in vitro results shown in this article indicate that DOX-liposome-loaded microbubbles could be a very interesting tool to obtain an efficient ultrasound-controlled DOX delivery in vivo.     

Increased accumulation and retention of micellar paclitaxel in drug-sensitive and P-glycoprotein-expressing cell lines following ultrasound exposure

Ultrasound treatment has been shown to enhance the uptake of both hydrophilic and hydrophobic compounds into PC3 and Huvec cell lines using an insonation regimen of a single 10-s burst of high-frequency (4 MHz), moderate intensity (32 W/cm(2)) ultrasound. The purpose of this work was to evaluate the effect of this ultrasound regimen on the cellular accumulation of paclitaxel (PTX) loaded in copolymer micellar of methoxy poly(ethylene glycol)-block-poly(D,L-lactide) (MePEG-b-PDLLA) in both drug-sensitive (MDCKII and MCF-7) and P-glycoprotein (Pgp)-expressing (MDCKII-MDR and NCI-ADR) cell lines. There were no effects of ultrasound on hydrodynamic diameters of micelles and the release of FRET pairs, indicating the integrity of micelles was maintained. There was a two-fold increase in intracellular PTX for all ultrasound-treated drug-sensitive cell lines and their respective drug-resistant counterparts compared with no ultrasound. Significant decreases in drug efflux rates were observed at 20, 40 and 60 min for both drug-sensitive and -resistant cell lines receiving ultrasound. The enhanced accumulation and retention of PTX by ultrasound resulted in greater cytotoxicity in both MDCKII and MDCKII-MDR cell lines, as indicated by the MTS assay. These data suggest that ultrasound may facilitate the uptake of intact paclitaxel-loaded micelles into cells, allowing greater retention of drug in both Pgp and non-Pgp-expressing cells.     

环孢霉素A对K562／DOX细胞药物积聚和外排的影响

目的：寻找克服肿瘤细胞多药耐药的方法。方法：以环孢霉素Ａ（ＣｓＡ）作为耐药逆转剂，用ＭＴＴ法体外药物敏感试验，观察ＣｓＡ对多药耐药白血病细胞株Ｋ５６２／ＤＯＸ的药物敏感性、细胞内药物的积聚和外排的影响。结果：ＣｓＡ可增强阿霉素（ＤＯＸ）对Ｋ５６２／ＤＯＸ的细胞毒作用，且存在剂量依赖关系。ＣｓＡ≥２μｇ／ｍｌ能较明显提高Ｋ５６２／ＤＯＸ对ＤＯＸ的敏感性。用２μｇ／ｍｌＣｓＡ处理后，Ｋ５６２／ＤＯＸ细胞内ＤＯＸ外排速度明显减慢，ＤＯＸ含量仅减少１２．３％，但对Ｋ５６２细胞内药物外排无影响。结论：ＣｓＡ能有效地减慢Ｋ５６２／ＤＯＸ细胞内ＤＯＸ外排速度，增加细胞内ＤＯＸ积聚。ＣｓＡ对Ｋ５６２细胞药物敏感性、细胞内药物外排和积聚均无影响。     

Ultrasound-triggered drug release and enhanced anticancer effect of doxorubicin-loaded poly(D,L-lactide-co-glycolide)-methoxy-poly(ethylene glycol) nanodroplets

A novel ultrasound-responsive doxorubicin (DOX)-loaded nanoparticulate system was prepared in this study. The DOX-loaded polymeric micelles were first prepared using poly(D,L-lactide-co-glycolide)-methoxy-poly(ethylene glycol) (PLGA-mPEG) with a high encapsulation efficiency of 89.2%. After filling with perfluoropentane (boiling point 29°C), the micelles were transformed into nanodroplets that were stable as a result of the PEG shell. The nanodroplets were transformed into nanobubbles at 37°C, and little drug was released if no ultrasound was exerted. Ultrasound-triggered drug release, with pH dependency, was shown. The DOX release percentage was 9.59% at pH 6.5 (also appeared in tumor) and only 2.22% at pH 7.4 after sonicating for 0.5 min at 37°C. The tumor inhibitory rate of Group III (DOX-loaded nanodroplets combined with ultrasound) was 84.3%, more than that of Group II (DOX-loaded nanodroplets), which was 60.4%. Moreover, the nanodroplets showed much lower toxicity than free drugs. The novel nanodroplets could be a promising anticancer drug delivery system.     

Controlled and targeted tumor chemotherapy by ultrasound-activated nanoemulsions/microbubbles

The paper reports the results of nanotherapy of ovarian, breast, and pancreatic cancerous tumors by paclitaxel-loaded nanoemulsions that convert into microbubbles locally in tumor tissue under the action of tumor-directed therapeutic ultrasound. Tumor accumulation of nanoemulsions was confirmed by ultrasound imaging. Dramatic regression of ovarian, breast, and orthotopic pancreatic tumors was observed in tumor therapy through systemic injections of drug-loaded nanoemulsions combined with therapeutic ultrasound, signifying efficient ultrasound-triggered drug release from tumor-accumulated nanodroplets. The mechanism of drug release in the process of droplet-to-bubble conversion is discussed. No therapeutic effect from the nanodroplet/ultrasound combination was observed without the drug, indicating that therapeutic effect was caused by the ultrasound-enhanced chemotherapeutic action of the tumor-targeted drug, rather than the mechanical or thermal action of ultrasound itself. Tumor recurrence was observed after the completion of the first treatment round; a second treatment round with the same regimen proved less effective, suggesting that drug-resistant cells were either developed or selected during the first treatment round.     

Ultrasound-Targeted Microbubble Destruction Enhances the Antitumor Efficacy of Doxorubicin in a Mouse Hepatocellular Carcinoma Model

The aim of the study described here was to investigate whether ultrasound-mediated microbubble destruction (UTMD) of targeted microbubbles conjugated with an anti-vascular endothelial growth factor receptor 2 (anti-VEGFR2) antibody can enhance the therapeutic effect of doxorubicin (DOX) on a mouse hepatocellular carcinoma (HCC) model bearing HEP-G2-RFP tumors. The growth of liver tumors in mice was inhibited by using Visistar VEGFR2 plus ultrasound irradiation and by DOX alone. DOX plus UTMD had an inhibitory effect on tumor growth beginning on the seventh day of treatment, while Visistar VEGFR2 alone and DOX alone had inhibitory effects beginning on the 11th day. DOX + UTMD significantly decreased tumor volume and tumor weight compared with DOX alone (p < 0.05) and Visistar VEGFR2 alone (p < 0.05). Compared with DOX alone and Visistar VEGFR2 alone, DOX + UTMD had the highest inhibitory effect on tumor angiogenesis and the highest apoptosis index. UTMD-targeted microbubbles can significantly enhance the antitumor effect of DOX on a mouse HCC model, inhibit angiogenesis and induce apoptosis in tumor cells.     

超声定位辐照载药微泡治疗卵巢癌移植瘤的实验研究

目的观察超声定位辐照载紫杉醇脂质微泡（paclitaxel—carrying liposome microbubbles，PLM）介导药物释放的方法对裸鼠人卵巢癌移植瘤的抑制效应。 方法对荷瘤鼠进行分组处理，包括超声定位辐照PLM组、单纯静脉给药组、超声定位辐照脂质微泡组、单纯静脉输注PLM组和生理盐水对照组。处理结束后剖取瘤块测其体积、质量，计算抑瘤率；并用免疫组化法检测肿瘤组织血管内皮生长因子（VEGF）表达。 结果各组的肿瘤体积、抑瘤率及VEGF表达均有差异（P＜0．01）。超声定位辐照PLM组的肿瘤体积、质量最小，抑瘤率最大，VEGF表达量最低。 结论超声定位辐照PLM的方法能有效介导药物释放，具有较强的体内抑瘤效果，有望成为新的肿瘤化疗给药方式。     

Folate receptor targeted biodegradable polymeric doxorubicin micelles.

Biodegradable polymeric micelles, self-assembled from a di-block copolymer of poly(D,L-lactic-co-glycolic acid) (PLGA) and poly(ethylene glycol) (PEG), were prepared to achieve folate receptor targeted delivery of doxorubicin (DOX). In the di-block copolymer structure of PLGA-b-PEG, DOX was chemically conjugated to a terminal end of PLGA to produce DOX-PLGA-mPEG, and folate was separately conjugated to a terminal end of PEG to produce PLGA-PEG-FOL. The two di-block copolymers with different functional moieties at their chains ends were physically mixed with free base DOX in an aqueous solution to form mixed micelles. It was expected that folate moieties were exposed on the micellar surface, while DOX was physically and chemically entrapped in the core of micelles. Flow cytometry and confocal image analysis revealed that folate conjugated mixed micelles exhibited far greater extent of cellular uptake than folate unconjugated micelles against KB cells over-expressing folate receptors on the surface. They also showed higher cytotoxicity than DOX, suggesting that folate receptor medicated endocytosis of the micelles played an important role in transporting an increased amount of DOX within cells. In vivo animal experiments, using a nude mice xenograft model, demonstrated that when systemically administered, tumor volume was significantly regressed. Biodistribution studies also indicated that an increased amount of DOX was accumulated in the tumor tissue.     

LyP-1-conjugated PEGylated liposomes: A carrier system for targeted therapy of lymphatic metastatic tumor

The application of liposomes in targeted therapy of lymphatic metastatic tumors has been hampered by the low uptake rate of liposome by metastatic lymph nodes. In this report, LyP-1, a peptide that can specifically bind tumor cells, tumor lymphatics and tumor-associated macrophages, was conjugated to liposomes for targeting and treating lymphatic metastatic tumors. Firstly, LyP-1-conjugated PEGylated liposomes loaded with fluorescein or doxorubicin (DOX) were prepared and showed satisfactory vesicle size and size distribution. The in vitro cellular uptake and in vivo near-infrared fluorescence imaging results showed that LyP-1 modification increased liposome uptake by tumor cells and metastatic lymph nodes, but did not increase uptake by normal lymph nodes. The immunofluorescence analysis evidenced that LyP-1-conjugated liposomes were distributed adjacent to tumor lymphatics and tumor-associated macrophages in metastatic lymph nodes. The pharmacodynamic study suggested that compared with unmodified liposomes, LyP-1-conjugated DOX-loaded liposomes exhibited enhanced inhibition effect on tumor cells in vitro and lymphatic metastatic tumors in vivo. Pathological examination showed that liposomal DOX caused reduced tissue damage to injection site compared with DOX solution. In summary, LyP-1-conjugated PEGylated liposomes could be targeted to metastatic lymph nodes based on their specific binding to tumor cells, tumor lymphatics and tumor-associated macrophages. They are a safe and effective drug delivery system of antineoplastic agents for targeted therapy of lymphatic metastatic tumors.     

Quantitative imaging of light-triggered doxorubicin release

The efficacy of chemotherapy is related, in large part, to the concentration of drug that reaches tumor sites. Doxorubicin (DOX) is a common anti-cancer drug that is also approved for use in liposomal form for the treatment of ovarian cancer. We recently developed a porphyrin-phospholipid (PoP)-liposome system that enables on demand release of DOX from liposomes using near infrared irradiation to improve DOX bioavailability. Owing to its intrinsic fluorescence, it is possible, and desirable, to quantify DOX concentration and distribution, preferably noninvasively. Here we quantified DOX distribution following light-triggered drug release in phantoms and an animal carcass using spatial frequency domain imaging. This study demonstrates the feasibility of non-invasive quantitative mapping of DOX distributions in target areas.OCIS codes: (170.0110) Imaging systems, (170.3880) Medical and biological imaging, (170.0170) Medical optics and biotechnology, (170.6935) Tissue characterization