Rupa R. Sawant

Enhanced cytotoxicity of TATp-bearing paclitaxel-loaded micelles in vitro and in vivo

Cell-penetrating peptide (TATp) was attached to the distal tips of polyethyleneglycol (PEG) moieties of polyethyleneglycol-phosphatidylethanolamine (PEG-PE) micelles loaded with paclitaxel (PCT). The TATp-modified micelles demonstrated an increased interaction with cancer cells compared to non-modified micelles resulting in a significant increase of the in vitro cytotoxicity to different cancer cells. TATp-modified PCT-loaded micelles were administered intratumorally in mice and the induction of apoptosis in tumor cells was studied after 48h with the Terminal Deoxynucleotidyl Transferase Biotin-dUTP Nick End Labeling (TUNEL) assay using free PCT and TATp-free PCT-loaded PEG-PE micelles as controls. A significant apoptotic cell death was observed in tumors treated with PCT-loaded micelles modified with TATp, while the treatment with free PCT or with non-modified PCT-loaded micelles resulted in much smaller number of TUNEL-positive cells within tumors.

Liposomes as ‘smart’ pharmaceutical nanocarriers

Since the discovery of liposomes, these phospholipid ‘bubbles’ have received enormous attention to be recognized as ‘smart’ pharmaceutical nanocarriers. Recently, much effort has been directed to the development of so-called ‘smart’ stimuli-sensitive liposomes that will respond to certain internal or external stimuli, such as, pH, temperature, redox potential or magnetic field. These programmable delivery systems can also be made ‘multifunctional’ so as to expose certain functions in an orchestrated manner which can be readily modulated by the stimulus. In this article, the evolution of liposomes with emphasis on the recent advances in stimuli-sensitive liposomes has been reviewed.

Challenges in Development of Targeted Liposomal Therapeutics

Liposomes, phospholipid vesicles with a bilayered membrane structure, have been widely used as pharmaceutical carriers for drugs and genes, in particular for treatment of cancer. To enhance the efficacy of the liposomal drugs, drug-loaded liposomes are targeted to the tumors by means of passive (enhanced permeability and retention mediated) targeting, based on the longevity of liposomes in blood and its accumulation in pathological sites with compromised vasculature, and active targeting, based on the attachment of specific ligands to the liposomal surface to bind certain antigens on the target cells. Antibody-targeted liposomes loaded with anticancer drugs demonstrate high potential for clinical applications. This review highlights evolution of liposomes for both passive and active targeting and challenges in development of targeted liposomal therapeutics specifically antibody-targeted liposomes.

The effect of dual ligand-targeted micelles on the delivery and efficacy of poorly soluble drug for cancer therapy

Abstract We prepared and evaluated transferrin (Tf) and monoclonal antibody (mAb) 2C5-modified dual ligand-targeted poly(ethylene glycol)–phosphatidylethanolamine micelles loaded with a poorly soluble drug, R547 (a selective adenosine triphosphate-competitive cyclin-dependent kinase inhibitor) for enhancement of targeting efficiency and cytotoxicity in vitro and in vivo to A2780 ovarian carcinoma compared to single ligand-targeted micelles. Micellar solubilization significantly improved the solubility of R547 from 1 to 800 μg/mL. The size of modified and non-modified micelles was 13–16 nm. Flow cytometry indicated significantly enhanced cellular association of dual ligand-targeted micelles compared to single ligand-targeted micelles. Confocal microscopy confirmed the Tf receptor-mediated endocytosis of rhodamine-labeled Tf-modified micelles after staining the micelle-treated cells with the endosomal marker Tf–Alexa488. The optimized dual-targeted micelles enhanced cytotoxicity in vitro against A2780 ovarian cancer cells compared to plain and single ligand-targeted micelles. Interestingly, in vivo anti-tumor efficacy was more pronounced for the preparation with a single-targeting ligand (Tf). The specific combination Tf and mAb 2C5 did not yield the expected increase in efficacy as was observed in vitro. This observation suggests that the relationships between targeting ligands in vivo could be more complex than in simplified in vitro systems, and the results of the optimization process should always be verified in vivo.

P-glycoprotein silencing with siRNA delivered by DOPE-modified PEI overcomes doxorubicin resistance in breast cancer cells

AIMS Multidrug resistance (MDR) mediated by overexpression of drug efflux transporters such as P-glycoprotein (P-gp), is a major problem, limiting successful chemotherapy of breast cancer. The use of siRNA to inhibit P-gp expression in MDR tumors is an attractive strategy to improve the effectiveness of anticancer drugs. METHOD We have synthesized a novel conjugate between a phospholipid (dioleoylphosphatidylethanolamine) and polyethylenimine (PEI) for siRNA delivery, for the purpose of silencing P-gp to overcome doxorubicin resistance in MCF-7 human breast cancer cells. RESULTS The dioleoylphosphatidylethanolamine-PEI conjugate enhanced the transfection efficacy of low-molecular-weight PEI, which was otherwise totally ineffective. In addition, the polyethylene glycol/lipid coating of the new complexes gave rise to small micelle-like nanoparticles with improved biocompatibility properties. Both coated and noncoated formulations delivered P-gp-specific siRNA to MDR cells. DISCUSSION The combination of doxorubicin and P-gp silencing formulations led to a twofold increase of doxorubicin uptake and a significant improvement of the therapeutic effect of doxorubicin in resistant cells.

Polyethyleneimine-lipid conjugate-based pH-sensitive micellar carrier for gene delivery.

A low molecular weight polyethyleneimine (PEI 1.8 kDa) was modified with dioleoylphosphatidylethanolamine (PE) to form the PEI-PE conjugate investigated as a transfection vector. The optimized PEI-PE/pDNA complexes at an N/P ratio of 16 had a particle size of 225 nm, a surface charge of +31 mV, and protected the pDNA from the action of DNase I. The PEI-PE conjugate had a critical micelle concentration (CMC) of about 34 μg/ml and exhibited no toxicity compared to a high molecular weight PEI (PEI 25 kDa) as tested with B16-F10 melanoma cells. The B16-F10 cells transfected with PEI-PE/pEGFP complexes showed protein expression levels higher than with PEI-1.8 or PEI-25 vectors. Complexes prepared with YOYO 1-labeled pEGFP confirmed the enhanced delivery of the plasmid with PEI-PE compared to PEI-1.8 and PEI-25. The PEI-PE/pDNA complexes were also mixed with various amounts of micelle-forming material, polyethylene glycol (PEG)-PE to improve biocompatibility. The resulting particles exhibited a neutral surface charge, resistance to salt-induced aggregation, and good transfection activity in the presence of serum in complete media. The use of the low-pH-degradable PEG-hydrazone-PE produced particles with transfection activity sensitive to changes in pH consistent with the relatively acidic tumor environment.

On-demand intracellular amplification of chemoradiation with cancer-specific plasmonic nanobubbles

Chemoradiation-resistant cancers limit treatment efficacy and safety. We show here the cancer cell–specific, on-demand intracellular amplification of chemotherapy and chemoradiation therapy via gold nanoparticle– and laser pulse–induced mechanical intracellular impact. Cancer aggressiveness promotes the clustering of drug nanocarriers and gold nanoparticles in cancer cells. This cluster, upon exposure to a laser pulse, generates a plasmonic nanobubble, the mechanical explosion that destroys the host cancer cell or ejects the drug into its cytoplasm by disrupting the liposome and endosome. The same cluster locally amplifies external X-rays. Intracellular synergy of the mechanical impact of plasmonic nanobubble, ejected drug and amplified X-rays improves the efficacy of standard chemoradiation in resistant and aggressive head and neck cancer by 100-fold in vitro and 17-fold in vivo, reduces the effective entry doses of drugs and X-rays to 2–6% of their clinical doses and efficiently spares normal cells. The developed quadrapeutics technology combines four clinically validated components and transforms a standard macrotherapy into an intracellular on-demand theranostic microtreatment with radically amplified therapeutic efficacy and specificity.

Cell-penetrating TAT peptide in drug delivery systems: Proteolytic stability requirements

The stability and activity of the HIV cell-penetrating TAT peptide (TATp) on the surface of TATp-modified micelles and liposomes in relation to its proteolytic cleavage was investigated. TATp moieties were attached to the surface of these nanocarriers using TATp modified with a conjugate of phosphatidyl ethanolamine with a ‘short’ PEG (PEG-PE). Following pre-incubation with trypsin, elastase, or collagenase, the proteolytic stability of TATp on the surface of these modified carriers was studied by HPLC with fluorescence detection using fluorenylmethyl chloroformate (FMOC) labeling. All tested enzymes produced a dose-dependent cleavage of TATp as shown by the presence of TATp Arg-Arg fragments. Inhibition of TATp cleavage occurred when these TATp-micelles were modified by the addition of longer PEG-PE blocks, indicating an effective shielding of TATp from proteolysis by these blocks. TATp-modified carriers were also tested for their ability to accumulate in EL-4, HeLa, and B16-F10 cells. Trypsin treatment of TATp-modified liposomes and micelles resulted in decreased uptake and cell interaction, as measured by fluorescence microscopy and fluorescence-activated cell sorting techniques. Furthermore, a decrease in the cytotoxicity of TATp-modified liposomes loaded with doxorubicin (Doxil) was observed following trypsin treatment. In conclusion, steric shielding of TATp is essential to ensure its in vivo therapeutic function.

Mixed PEG–PE/vitamin E tumor-targeted immunomicelles as carriers for poorly soluble anti-cancer drugs: Improved drug solubilization and enhanced in vitro cytotoxicity

Two poorly soluble, potent anti-cancer drugs, paclitaxel and camptothecin, were successfully solubilized by mixed micelles of polyethylene glycol-phosphatidyl ethanolamine (PEG-PE) and vitamin E. Drug-containing micelles were additionally modified with anti-nucleosome monoclonal antibody 2C5 (mAb 2C5), which can specifically bring micelles to tumor cells in vitro. The optimized micelles had an average size of about 13-22 nm and the immuno-modification of micelles did not significantly change it. The solubilization of both drugs by the mixed micelles was more efficient than by micelles made of PEG-PE alone. Solubilization of camptothecin in micelles prevented also the hydrolysis of active lactone form of the drug to inactive carboxylate form. Drug-loaded mixed micelles and mAb 2C5-immunomicelles demonstrated significantly higher in vitro cytotoxicity than free drug against various cancer cell lines.

Surface modification of liposomes with rhodamine-123-conjugated polymer results in enhanced mitochondrial targeting

A novel mitochondrial-targeted liposomal drug-delivery system was prepared by modification of the liposomal surface with a newly synthesized polymer, rhodamine-123 (Rh123)-PEG-DOPE inserted into the liposomal lipid bilayer. This novel polymer was synthesized by conjugating the mitochondriotropic dye Rh123, with the amphiphilic polyethylene glycol–phosphatidylethanolamine (PEG-PE) conjugate. The modified liposomes showed better uptake by cells (HeLa, B16F10) estimated by fluorescence microscopy and FACS analysis. The co-localization study with stained mitochondria as well as with the isolation of mitochondria of the cultured cells after their treatment with Rh123 liposomes showed a high degree of accumulation of the modified liposomes in the mitochondria. We also prepared mitochondrial-targeted and nontargeted paclitaxel (PCL)-loaded liposomes. Mitochondrial-targeted PCL-loaded liposomes demonstrated enhanced cytotoxicity toward cancer cells compared with nontargeted drug-loaded liposomes or free PCL. Thus, Rh123-modified liposomes target mitochondria efficiently and can facilitate the delivery of a therapeutic payload to mitochondria.