Targeting and modulating infarct macrophages with hemin formulated in designed lipid-based particles improves cardiac remodeling and function.

Uncontrolled activation of pro-inflammatory macrophages after myocardial infarction (MI) accelerates adverse left ventricular (LV) remodeling and dysfunction. Hemin, an iron-containing porphyrin, activates heme oxygenase-1 (HO-1), an enzyme with anti-inflammatory and cytoprotective properties. We sought to determine the effects of hemin formulated in a macrophage-targeted lipid-based carrier (denoted HA-LP) on LV remodeling and function after MI. Hemin encapsulation efficiency was ~100% at therapeutic dose levels. In vitro, hemin/HA-LP abolished TNF-α secretion from macrophages, whereas the same doses of free hemin and drug free HA-LP had no effect. Hemin/HA-LP polarized peritoneal and splenic macrophages toward M2 anti-inflammatory phenotype. We next induced MI in mice and allocated them to IV treatment with hemin/HA-LP (10mg/kg), drug free HA-LP, free hemin (10mg/kg) or saline, one day after MI. Active in vivo targeting to infarct macrophages was confirmed with HA-LP doped with PE-rhodamine. LV remodeling and function were assessed by echocardiography before, 7, and 30days after treatment. Significantly, hemin/HA-LP effectively and specifically targets infarct macrophages, switches infarct macrophages toward M2 anti-inflammatory phenotype, improves angiogenesis, reduces scar expansion and improves infarct-related regional function. In conclusion, macrophage-targeted lipid-based drug carriers with hemin switch macrophages into an anti-inflammatory phenotype, and improve infarct healing and repair. Our approach presents a novel strategy to modulate inflammation and improve infarct repair.

Treatment of respiratory damage in mice by aerosols of drug-encapsulating targeted lipid-based particles.

The purpose of this study was to develop a treatment for respiratory damage caused by exposure to toxic industrial chemicals (TICs), including mass casualty events, by aerosols of dexamethasone and/or N-acetyl cysteine formulated in targeted lipid-based particles. Good encapsulation, performance as slow-release drug depots, conservation of matter, and retention of biological activity were obtained for the three drug-carrier formulations, pre- and post-aerosolization. Weight changes over a 2week period were applied, deliberately, as a non-invasive clinical parameter. Control mice gained weight continuously, whereas a non-lethal 30minute exposure of mice to 300ppm Cl2 in air showed a two-trend response. Weight loss over the first two days, reversing thereafter to weight gain, but at a rate and level significantly slower and smaller than those of the control mice, indicating the chlorine damage was long-term. The weight changes of Cl2-exposed mice given the inhalational treatments also showed the two-trend response, but the weight gain rates and levels were similar to those of the control mice, reaching the weight-gain range of the control mice. Following this proof of concept, studies are now extended to include additional TICs, and biochemical markers of injury and recovery.

Targeting macrophage subsets for infarct repair.

Macrophages are involved in every cardiovascular disease and are an attractive therapeutic target. Macrophage activation is complex and can be either beneficial or deleterious, depending upon its mode of action, its timing, and its duration. An important macrophage characteristic is its plasticity, which enables it to switch from one subset to another. Macrophages, which regulate healing and repair after myocardial infarction, have become a major target for both treatment and diagnosis (theranostic). The aim of the present review is to describe the recent discoveries related to targeting and modulating of macrophage function to improve infarct repair. We will briefly review macrophage polarization, plasticity, heterogeneity, their role in infarct repair, regeneration, and cross talk with mesenchymal cells. Particularly, we will focus on the potential of macrophage targeting in situ by liposomes. The ability to modulate macrophage function could delineate pathways to reactivate the endogenous programs of myocardial regeneration. This will eventually lead to development of small molecules or biologics to enhance the endogenous programs of regeneration and repair.

Cancer cell sensitization and improved treatment efficacy by combined sodium butyrate and paclitaxel formulations is cancer-type specific.

We queried whether cancer treatment by combinations of paclitaxel and butyrate - free or formulated in drug delivery systems - can improve therapeutic responses compared to each drug alone. Combination treatments were conducted with HT-29 and HeLa cells, as representatives of differentiation-induced and cell-death-induced cancer lines, respectively. Pre-treatment of the HT-29 cells with butyrate (at doses inducing differentiation), followed by butyrate+paclitaxel generated changes in cell cycle profile, increased the level of dead cells beyond that of each drug alone, and allowed reduction in paclitaxel doses. A similar combination treatment of HeLa cells was detrimental, indicating that whether the combination is beneficial or not is cancer-type specific. We hypothesize that while butyrate-treated HT-29 cells became sensitive to paclitaxel-induced Fas-mediated apoptosis, butyrate-adapted HeLa cells became apoptosis-resistant. We next tested the same drug combination on HT-29 cells, but each drug in a specific tumor-targeted carrier. The combination of drug carriers outperformed an equidose combination of the free drugs, showing potential to achieve high therapeutic responses (even in drug-resistant cells) at significantly lower and detergent-free paclitaxel doses, which should allow for reduction in adverse effects and risks of toxicity.

Hyaluronan-modified and regular multilamellar liposomes provide sub-cellular targeting to macrophages, without eliciting a pro-inflammatory response.

Macrophages, pivotal cells in onset and progression of inflammation, can benefit from sub-cellular drug targeting to the molecular loci of drug action, whether cell membrane or cell interior. Postulating manipulation of liposome size and surface properties can provide sub-cellular targeting, we studied: thermodynamics of liposome-macrophage binding; liposome cellular localizations; liposome safety including pro-inflammatory cytokine production. We aimed at extending the body of knowledge on interactions of regular unilamellar (RL-ULV) and multilamellar (RL-MLV) liposomes with macrophages. We investigated, for the first time, the interactions of hyaluronan (HA) surface-modified liposomes (HA-ULV and HA-MLV) with macrophages, with respect to multiple equilibria binding combined with cellular localization. Macrophages bound all four liposome types, substantially-favoring the two MLV species over the two ULV species, and internalizing only RL-MLV. Three macrophage-internalization inhibitors (2-deoxyglucose, LY294002 and Wortmannin) reduced RL-MLV internalization but not binding affinity nor binding capacity. Both MLV types were not detrimental to cell proliferation, nor did they elicit TNF-α production in resting and in LPS-activated macrophages. Moreover, a 24-hour exposure of LPS-activated macrophages to HA-MLV reduced TNF-α production by 40%, indicating potential for anti-inflammatory activity. In conclusion RL-MLV and HA-MLV are the liposomes of choice for delivering anti-inflammatory drugs to the macrophage surface or its interior, according to the loci of drug action.

Paclitaxel-clusters coated with hyaluronan as selective tumor-targeted nanovectors.

Paclitaxel (PTX) is a widely used anti-tumor agent in the treatment of solid tumors. Lack of selective strategies to target PTX into tumor cells together with poor solubility necessitating detergent, are severe clinical limitations. To address these hurdles, we devised a strategy that utilized PTX insolubility, mixing it with lipids that self-assemble into nanoparticle-like clusters. These clusters were then coated with hyaluronan, a glycosaminoglycan (GAG), and termed PTX-GAGs. These particles, delivered PTX selectively into tumor cells in a CD44-dependent manner. Injected systemically to mice bearing solid tumors, the PTX-GAGs showed high safety profile and tumor accumulation. Tumor progression was exponential upon treatment with free PTX or PTX in albumin nanoparticles (the FDA-approved Taxol and Abraxane, respectively). Under the same conditions, PTX-GAGs induced tumor arrest and were as potent as a 4-fold higher Taxol dose. Our findings suggest GAGs merit further investigation as vehicles for taxanes, and may be applicable as carriers in other therapeutic settings.

Novel steroid carbamates reverse multidrug-resistance in cancer therapy and show linkage among efficacy, loci of drug action and P-glycoprotein's cellular localization.

P-glycoprotein (Pgp) is a major ABC transporter responsible for multidrug-resistance (MDR) in cancer chemotherapy. Pre-clinical MDR modulation studies identified promising chemosensitizers, but none are in the clinic yet. Two novel progesterone-derived carbamates (11-carbamic acid N,N-dibenzyl progesterone ester and 11-carbamic acid N,N-dibutyl progesterone ester) were examined as potential chemosensitizers in the Pgp-expressing human colon cancer line HCT-15, applying the classical MDR-drugs paclitaxel and doxorubicin. The major findings were: (1) Pgp was expressed in the HCT-15 cells in both the cell and the nuclear membranes, (2) at the low dose range of 1-5 microM, each new candidate: (i) increased cytotoxicity of doxorubicin (15-fold) and (separately) of paclitaxel (40-fold), (ii) induced an increase in intracellular accumulation, 60% (4h) for doxorubicin and 300% (18h) for paclitaxel, (iii) reduced drug efflux from the cell, 2-fold and 4-fold for doxorubicin and for paclitaxel, respectively. Based on detailed kinetic analysis, using liposomes to model paclitaxel diffusion through cell membranes, efflux slowdown can be attributed to reduction in the rate constant of drug diffusion through Pgp, and not to Pgp blockage. Chemosensitization was consistently-better for paclitaxel (cytosol-operating) than for doxorubicin (nuclear-operating) implying linkage between P-glycoprotein localization and loci of drug action. Mapping intracellular locations of MDR-pumps may assist therapeutic strategies.

A color discriminating broad range cell staining technology for early detection of cell transformation.

BACKGROUND: Advanced diagnostic tools stand today at the heart of successful cancer treatment. CellDetect(R) is a new histochemical staining technology that enables color discrimination between normal cells and a wide variety of neoplastic tissues. Using this technology, normal cells are colored blue/green, while neoplastic cells color red. This tinctorial difference coincides with clear morphological visualization properties, mainly in tissue samples. Here we show that the CellDetect(R) technology can be deployed to distinguish normal cells from transformed cells and most significantly detect cells in their early pre-cancerous transformed state. MATERIALS AND METHODS: In tissue culture, we studied the ability of the CellDetect(R) technology to color discriminate foci in a number of two stage transformation systems as well as in a well defined cellular model for cervical cancer development, using HPV16 transformed keratinocytes. RESULTS: In all these cellular systems, the CellDetect(R) technology was able to sensitively show that all transformed cells, including pre-cancerous HPV 16 transformed cells, are colored red, whereas normal cells are colored blue/green. The staining technology was able to pick up: (i) early transformation events in the form of small type 1 foci (non-invasive, not piled up small, with parallel alignment of cells), and (ii) early HPV16 transformed cells, even prior to their ability to form colonies in soft agar. The study shows the utility of the CellDetect(R) technology in early detection of transformation events.

Liposomal dexamethasone-diclofenac combinations for local osteoarthritis treatment.

Conventional chronic and acute treatments for osteoarthritis (OA) are by oral NSAIDs (such as diclofenac) and intra-articular injected glucocorticosteroids (such as dexamethasone). In free form, diclofenac and dexamethasone generate severe adverse effects with risks of toxicity. To reduce these drawbacks, we investigated local injections of liposomal formulations for diclofenac and dexamethasone (each alone, and their combination). Bioadhesive liposomes carrying hyaluronan (HA-BAL) or collagen (COL-BAL) as their surface-anchored ligand were used for the task. Each drug alone or their combination showed high efficiency encapsulations (> or =80%) and performance as slow-release depots (half-lives in the range of 1-3 days under the fastest conditions). Employing RIA and immunoblot assay techniques, it was verified that the encapsulated drugs retained their biological activities: inhibitions of Cyclooxygenases enzyme-activity (diclofenac) and of Cyclooxygenases protein-expression (dexamethasone). Using live-animal MRI, a single intra-articular injection of each liposome-drug(s) formulation sufficed to reduce knee joint inflammation in OA rats over a time span of 17 days, HA-BAL better than COL-BAL. The most effective treatment was by the combination of both drugs in HA-BAL, a single dose reducing the inflammation volume down to 12.9% from initial over that time span. We find all three HA-BAL formulations worthy of further studies.

A novel Diclofenac-carrier for local treatment of osteoarthritis applying live-animal MRI.

The prevailing chronic treatment for osteoarthritis--oral administration of NSAIDs--is accompanied by severe adverse effects and risks of gastrointestinal (GI) toxicity. The working hypothesis of this study was that increased NSAID-efficacy and alleviation of adverse effects can be achieved by local administration of a new slow-release NSAID-carrier formulation. Diclofenac was the test NSAID and collagomers--novel vesicular-shaped microparticles based on collagen-lipid conjugates--were the carriers. Collagomers were stable in simulated synovial fluid and showed: high-efficiency drug encapsulation (85%); slow drug release (tau((1/2))=11 days); high affinity to target cells (Kd=2.6 nM collagen). In vitro activity of Diclofenac released from the carriers was similar to fresh drug solutions. Diclofenac-collagomer therapeutic effects were studied in osteoarthritis-induced rats, using live-animal MRI. A single intra-articular injection of the Diclofenac-collagomer formulation reduced inflammation over 3 weeks significantly vs. untreated animals (p<0.001), and vs. the conventional treatment which is free drug PerOs (p<0.03). Bypassing the GI, the novel treatment circumvents adverse effects of the conventional approach. In conclusion, the collagomers performed as functional Diclofenac-depots for local treatment of osteoarthritis, avoiding GI adverse effects. The in vivo results merit further investigations of this novel NSAID formulation as a valid option to the conventional treatment.

Insights into modeling streptozotocin-induced diabetes in ICR mice.

Streptozotocin (STZ)-induced diabetes in ICR mice is often used to model diabetes mellitus and its complications, as well as other pathologies. In studies of diabetes progression and effects of newly developed treatments, experimental results may be difficult to interpret because blood glucose levels (BGLs) of untreated diabetic control animals tend to decline substantially during typical experimental time spans of 8-11 h. To address this problem, the authors examined several experimental conditions that might affect BGL stability, including STZ dose, initial mouse weight, fasting regimen and light:dark cycle. The authors found that diabetes severity was dependent on initial mouse weight and that weight loss after diabetes induction was less severe in heavier mice. Furthermore, a dose of 150 mg STZ per kg body weight was sufficient to induce stabilized acute diabetes without causing many complications. Finally, BGL could be stabilized in diabetic mice that were not treated with insulin by avoiding pre-fasting before an 8-h experiment and by allowing mice limited access to food during the experiment.

Three-dimensional characterization of drug-encapsulating particles using STEM detector in FEG-SEM.

New drug-encapsulating particles were investigated using bright field (BF) scanning transmission electron microscopy (STEM) in a field emission gun (FEG) scanning electron microscope (SEM). Thickness characterization was done based on measuring the effective cross-section for interaction in our sample-detector configuration using calibration particles. A simplified analytical model, taking account of BF-STEM contrast and effective cross-section for interaction, was utilized for transforming projected two-dimensional BF-STEM images into three-dimensional thickness images. The three-dimensional characterization is demonstrated on a new family of biological materials composed of submicron to micron drug-free and drug-encapsulating particles. The importance of using BF-STEM in SEM, relative to other electron microscopy methods, is discussed as well as the lateral and depth resolution.

Treatment of resistant human colon cancer xenografts by a fluoxetine-doxorubicin combination enhances therapeutic responses comparable to an aggressive bevacizumab regimen.

Pre-clinical studies of multidrug resistance (MDR) usually address severe resistance, yet moderate MDR is already clinically-impeding. The purpose of this study was to characterize moderate drug resistance in human colon cancer, and it's modulation by fluoxetine. In vitro fluoxetine enhanced doxorubicin's cytotoxicity (10-fold), increased doxorubicin's intracellular accumulation (32%) and decreased efflux of intracellular doxorubicin (70%). In vivo, mild treatment with a doxorubicin-fluoxetine combination slowed-down tumor progression significantly (p<0.001 vs. doxorubicin alone), comparable to aggressive treatment with bevacizumab. Collectively, our results suggest that combinations of fluoxetine with chemotherapeutic drugs (P-glycoprotein substrates) are worthy of further pursuit for moderate MDR in the clinic.

Electrochemical lab on a chip for high-throughput analysis of anticancer drugs efficiency.

We describe a new method for rapid, sensitive, and high-throughput detection of colon cancer cells' response to differentiation therapy, using a novel electrochemical lab-on-a-chip system. Differentiation-inducing agents such as butyric acid and its derivatives were introduced to miniature colon cancer samples within the nanovolume chip chambers. The efficacy of each of the differentiation-inducing agents was evaluated by electrochemical detection of the cellular enzymatic activity level, whereas reappearance of normal enzymatic activity denotes effective therapy. The results demonstrate the ability to evaluate simultaneously multiplex drug effects on miniature tumor samples (approximately 15 cells) rapidly (5 minutes) and sensitively, with quantitative correlation between cancer cells' number and the induced current. The use of miniature analytical devices is of special interest in clinically relevant samples, in that it requires less tissue for diagnosis, and enables high-throughput analysis and comparison of various drug effects on one small tumor sample, while maintaining uniform biological and environmental conditions.

Cyclooxygenase inhibition by diclofenac formulated in bioadhesive carriers.

Adverse effects and gastrointestinal toxicity limit the use of Diclofenac, a frequently-used NSAID for treatments of rheumatic disorders and other chronic inflammatory diseases. Diclofenac-carrier formulations may alleviate adverse effects, increase efficacy and allow local administration. We report here our first step, biophysical and biochemical investigations of Diclofenac formulated in our previously-developed bioadhesive liposomes carrying hyaluronan (HA-BAL) or collagen (COL-BAL) on their surface. Both liposome types encapsulated Diclofenac at high efficiency, encapsulated doses reaching 13 mg drug/ml, and performed as sustained-release Diclofenac depots, half-lives of drug release (under fastest conditions) ranging from 1 to 3 days. Therapeutic activity of liposomal Diclofenac was evaluated in CT-26 cells that possess the CD44 hyaluronan receptors and integrins, and are a bench-mark for intracellular COX enzymes. HA-BAL and COL-BAL showed high cellular-affinity that was 40 fold and 6 fold over that of regular liposomes. Free, and liposome-encapsulated, Diclofenac showed similar activities. For example: 2-3nM Diclofenac given to intact cells generated COX-inhibition levels in the range of 60-70% for free drug and for encapsulated drug in COL-BAL and in HA-BAL. We propose these novel Diclofenac formulations possess key physicochemical and biochemical attributes for task performance, meriting the next step into in vivo studies.

Nanocarriers as an emerging platform for cancer therapy.

Nanotechnology has the potential to revolutionize cancer diagnosis and therapy. Advances in protein engineering and materials science have contributed to novel nanoscale targeting approaches that may bring new hope to cancer patients. Several therapeutic nanocarriers have been approved for clinical use. However, to date, there are only a few clinically approved nanocarriers that incorporate molecules to selectively bind and target cancer cells. This review examines some of the approved formulations and discusses the challenges in translating basic research to the clinic. We detail the arsenal of nanocarriers and molecules available for selective tumour targeting, and emphasize the challenges in cancer treatment.

Fluoxetine and reversal of multidrug resistance.

This review centers on recent findings with respect to modulating cancer multidrug resistance (MDR) with the well-known antidepressant fluoxetine (prozac). The MDR phenomena and mechanisms are discussed, including the roles of ABC transporters as MDR-pumps and the potential involvement of cancer stem cells. The three generations of MDR reversal agents (chemosensitizers) are reviewed, introducing the concept of single-pump and multi-pump agents. The current status of chemosensitization is summarized, pointing-out the need for additional agents and outlining experimental criteria for testing novel candidates. Major in vitro and in vivo findings are summarized showing that fluoxetine is a chemosensitizer of the multi-pump type, and proposing it be considered a fourth-generation chemosensitizer. In concluding, we contemplate future prospects of modulating MDR in the clinic.

Lipsome-formulated enzymes for organophosphate scavenging: butyrylcholinesterase and Demeton-S.

Butyrylcholinesterase-encapsulating bioadhesive liposomes are investigated as prophylactic scavengers of organophosphates for local administration to skin, eyes, airways, and lungs-gates through which organophosphates penetrate living systems. The systems were optimized with respect to: encapsulation efficiency; type of bioadhesive ligand bound to liposomes (collagen or hyaluronan); ligand density at the liposomal surface; retention of encapsulated-enzyme activity; protection of encapsulated enzyme from proteolysis; and scavenging the model organophosphate Demeton-S (DS). Monolayers of PC-12 cells were selected for feasibility testing based on: high affinity binding of the bioadhesive liposomes-DeltaG0 release upon binding ranged from -9 to -12 kcal/mol ligand; ability to mimic an organophosphate attack upon intact cells and measuring its impact on intracellular acetylcholinesterase. Under attack, unprotected cells lost 80-90% of intracellular enzyme activity. The loss was reduced to 20-30% for protected cells (pre-treated with the formulations), at the expense of liposomal Butyrylcholinesterase. These results support our prophylactic approach.

Fluoxetine inhibits multidrug resistance extrusion pumps and enhances responses to chemotherapy in syngeneic and in human xenograft mouse tumor models.

Multidrug resistance (MDR) operated by extrusion pumps such as P-glycoprotein and multidrug-resistance-associated-proteins, is a major reason for poor responses and failures in cancer chemotherapy. MDR modulators (chemosensitizers) were found among drugs approved for noncancer indications and their derivatives. Yet toxicity, adverse effects, and poor solubility at doses required for MDR reversal prevent their clinical application. Among newly designed chemosensitizers, some still suffer from toxicity and adverse effects, whereas others progressed to clinical trials. Diversities among tumors and among MDR pumps indicate a need for several clinically approved MDR modulators. Here we report for the first time that fluoxetine (Prozac), the well-known antidepressant, is a highly effective chemosensitizer. In vitro, fluoxetine enhanced (10- to 100-fold) cytotoxicity of anticancer drugs (doxorubicin, mitomycin C, vinblastine, and paclitaxel) in drug-resistant but not in drug-sensitive cells (5 and 3 lines, respectively). Fluoxetine increased drug accumulation within MDR-cells and inhibited drug efflux from those cells. In vivo, fluoxetine enhanced doxorubicin accumulation within tumors (12-fold) with unaltered pharmacokinetics. In four resistant mouse tumor models of both syngeneic and human xenograft, combination treatment of fluoxetine and doxorubicin generated substantial (P < 0.001) improvements in tumor responses and in survivals (2- to 3-fold). Moreover, fluoxetine reversed MDR at doses that are well below its human safety limits, free of the severe dose-related toxicity, adverse effects, and poor solubility that are obstacles to other chemosensitizers. This low-dose range, together with the findings reported here, indicate that fluoxetine has a high potential to join the arsenal of MDR reversal agents that may reach the clinic.

Tumor-targeted hyaluronan nanoliposomes increase the antitumor activity of liposomal Doxorubicin in syngeneic and human xenograft mouse tumor models.

Naturally occurring high-Mr hyaluronan, bound to the surface of nanoliposomes (denoted targeted hyaluronan liposomes, or tHA-LIP), is a candidate for active targeting to tumors, many of which overexpress the hyaluronan receptors CD44 and RHAMM. The surface-bound hyaluronan also provides a hydrophilic coat that, similar to polyethylene glycol, may promote long-term circulation. We recently reported the successful targeting of mitomycin C, mediated by tHA-LIP, in tumor-bearing syngeneic mice. Hypothesizing that this targeting is carrier-specific, rather than drug-specific, we report here studies with doxorubicin (DXR)-loaded tHA-LIP, in syngeneic and human xenograft models. Saline, free DXR, DXR-loaded nontargeted liposomes (nt-LIP), and Doxil served as controls. The tHA-LIP were long-circulating, more than all controls, in healthy and tumor-bearing (C57BL/6/B16F10.9; BALB/c/C-26) mice. Mediated by tHA-LIP, DXR accumulation in tumor-bearing lungs was 30-, 6.7-, and 3.5-fold higher than free DXR, nt-LIP, and Doxil, respectively. Key indicators of therapeutic responses--tumor progression, metastatic burden, and survival--were superior (P < .001) in animals receiving DXR-loaded tHA-LIP compared with controls, in tumor-bearing syngeneic mice (BDF1/P388/ADR ascites, C57BL/6/B16F10.9 lung metastasis, and BALB/c/C-26 solid tumors), and in nude mice bearing PANC-1 solid tumors. In conclusion, tHA-LIP, performing as tumor-targeted carriers, have the potential to join the arsenal of carrier-formulated anticancer drugs.