Temperature-sensitive liposomes for co-delivery of tamoxifen and imatinib for synergistic breast cancer treatment

Co-delivery of chemotherapeutic agents using nanocarriers is a promising strategy for enhancing therapeutic efficacy of anticancer agents. The aim of this work was to develop tamoxifen and imatinib dual drug loaded temperature-sensitive liposomes to treat breast cancer. Liposomes were prepared using 1, 2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC), monopalmitoyl-2-hydroxy-sn-glycero-3-phosphocholine (MPPC), and different surface active agents. The liposomes were characterized for the average particle size, zeta potential, transition temperature, and drug release below and above liposomal transition temperature. The temperature-sensitive liposomes co-encapsulated with tamoxifen and imatinib were investigated for their synergistic activity against MCF-7 and MDA-MB-231 breast cancer cells. The liposomal nanoparticles showed a transition temperature of 39.4?°C and >70% encapsulation efficiency for tamoxifen and imatinib. The temperature-responsive liposomes showed more than 80% drug released within 30?min above transition temperature. Dual drug loaded liposomes showed synergistic growth inhibition against MCF-7 and MDA-MB-231 breast cancer cells. Co-delivery of tamoxifen and imatinib using temperature-sensitive liposomes can be developed as a potential targeting strategy against breast cancer.     

Hyaluronic acid modified pH-sensitive liposomes for targeted intracellular delivery of doxorubicin

Context: Surface-modified pH-sensitive liposomal system may be useful for intracellular delivery of chemotherapeutics.

Objective: Achieving site-specific targeting with over-expressed hyaluronic acid (HA) receptors along with using pH sensitive liposome carrier for intracellular drug delivery was the aim of this study.

Materials and methods: Stealth HA-targeted pH-sensitive liposomes (SL-pH-HA) were developed and evaluated to achieve effective intracellular delivery of doxorubicin (DOX) vis–a-vis enhanced antitumor activity.

Results: The in vitro release studies demonstrated that the release of DOX from SL-pH-HA was pH-dependent, i.e. faster at mildly acidic pH ～5, compared to physiological pH ～7.4. SLpH-HA was evaluated for their cytotoxicity potential on CD44 receptor expressing MCF-7 cells. The half maximal inhibitory concentration (IC50) of SL-pH-HA and SL-HA were about 1.9 and 2.5?μM, respectively, after 48?h of incubation. The quantitative uptake study revealed higher localization of targeted liposomes in the receptor positive cells, which was further confirmed by fluorescent microscopy. The antitumor efficacy of the DOX-loaded HA-targeted pH-sensitive liposomes was also verified in a tumor xenograft mouse model.

Discussion: DOX was efficiently delivered to the tumor site by active targeting via HA and CD44 receptor interaction. The major side-effect of conventional DOX formulation, i.e. cardiotoxicity was also estimated by measuring serum enzyme levels of LDH and CPK and found to be minimized with developed formulation. Overall, HA targeted pH-sensitive liposomes were significantly more potent than the non-targeted liposomes in cells expressing high levels of CD44.

Conclusion: Results strongly implies the promise of such liposomal system as an intracellular drug delivery carrier developed for potential anticancer treatment.     

Liposomal Anticancer Drugs as Agents to be used in Combination with other Anticancer Agents: Studies on a Liposomal Formulation with two Encapsulated Drugs

Abstract

When considering the use of combination therapies with liposomal anticancer agents several approaches can be defined. One approach could rely on administration of one liposomal formulation with more than one entrapped cytotoxic drug. This study focuses on an assessment of a liposomal formulation containing vincristine and mitoxantrone. Distearoyl phosphatidylcholine (DSPC)/Cholesterol (Choi) (55:45 molar ratio) liposomes were loaded with vincristine using transmembrane pH gradients. These systems were subsequently incubated with mitoxantrone to effect uptake of the second drug. Retention of both drugs was determined in vitro and in vivo. In vitro drug release indicated >95% retention of mitoxantrone and approximately 75% retention of vincristine when liposomes were prepared with an initial interior pH of 2.0. In vivo results however, demonstrated that greater than 80% of the encapsulated vincristine was released within 1 hour following i.v. administration. The instability of a liposomal formulation containing two anticancer drugs following i.v. administration may be a consequence of a combination of factors including drug-loading induced collapse of the transmembrane pH gradient, loss due to osmotic effects and an associated insertion of serum proteins into the bilayer, as well as the presence of a large biological “sink” which can alter the transbilayer drug gradient in favor of drug release.     

Effect of cisplatin containing liposomes formulated by unsaturated chain-containing lipids on gynecological tumor cells

Gynecological tumors are major therapeutic areas of platinum-based anticancer drugs. Here, we report the characterization and in vitro biological assays of cisplatin-containing Egg L-α-phosphatidylcholine liposomes with different amounts of cholesterol. Dynamic light scattering estimated sizes of all obtained liposomes in the 100?nm range that are suitable for in vivo use. On the basis of these data and of the drug loading values, the best formulation has been selected. Stability and drug release properties of platinum-containing liposomes have been verified in serum. The growth inhibitory effects of both liposomal and free drug in a panel of ovarian and breast human cancer cell lines, characterized by a different drug sensitivity, give comparable or better results with respect to free cisplatin drug.     

Effects of liposomal encapsulation on the antioxidant activity of lipophilic prodrugs of idebenone

Context: Increasing the lipophilicity and/or amphiphilicity of drugs is a potential strategy to improve loading and retention in lipid-based carriers, such as liposomes or lipid nanoparticles.

Objective: Idebenone (IDE), an antioxidant compound structurally related to coenzyme Q, or amphiphilic prodrugs of IDE with lipoamino acids, were loaded in neutral or negatively charged SUVET unilamellar liposomes to achieve a controlled release.

Methods: Technological properties of these systems in the presence of loaded drugs were evaluated in terms of vesicle size, homogeneity, and surface charge, as well as in vitro drug release. The effect of liposomal carrier on the in vitro antioxidant activity of the prodrugs was evaluated from using different biochemical assays on murine astrocyte cultures.

Results and discussion: Although a good loading efficiency was obtained, liposomes were not able to release efficiently the encapsulated drugs, at least in the in vitro serum-free conditions used for the biological tests. However, in some cases, such as in the comet assay, encapsulation of IDE prodrugs in liposomes allowed for the improvement of their protective activity, compared to the free compounds, against the oxidative damage induced on cultured astrocytes.

Conclusions: Experimental in vitro data suggested that the high affinity shown by these lipophilic IDE derivatives for the liposomal carriers negatively affect their biological activity.     

Pharmacological Effects of Carboplatin-Liposomes (CPL) in Mice: A Reviev of Present Knowledge

Abstract

Carboplatin was encapsulated in reverse phase evaporation vesicles (REV) consisting of hydrogenated egg phosphatidylcholine and cholesterol (HEPC:CH) in a molar ratio of 1 : 0.25. Both antitumor effects, influence on hematopoiesis and cytokine levels were measured in mice after i.p. or i.v. injection in comparison to the free drug. In the syngeneic murine P 388 leukemia and the Meth A sarcoma liposomal encapsulation resulted in a loss of antitumor activity. On contrary, in 3/6 breast carcinomas xenografted to nude mice CPL had a superior tumor inhibiting effect compared to free carboplatin, which could be further improved by using the combination of free and liposomal drug. As reported earlier CPL induced a five- or tenfold, at least 30 days lasting increase in peripheral white blood cells after only one single i.v. or i.p. injection, respectively. A second administration in a 7–10 weeks distance was able to a repeated stimulation. The colony forming activity and the percentage of cells in S-phase were elevated in spleen cells three days after treatment of mice with CPL while these parameters remained unchanged in the bone marrow. Serum taken from CPL-treated nude or normal mice induced significantly colony formation of bone marrow cells in a soft agar culture. Concerning side effects, CPL led to a 15 days lasting blockade of RES (measured by carbon clearance), to a 7 days lasting increase of serum glutamate oxalacetate transaminase and a diminuation of body weight while the blood urea levels as parameter of kidney toxicity were in normal range. A combination of CPL with either cyclophosphamide or free carboplatin prevented the cytostatic-induced leukopenia.     

Inhibition by Liposomal Cholesterol of Streptococcus Pneumoniae Induced Lung Epithelial Cell Damage

Abstract

Streptococcus pneumoniae was shown to be capable of lysing A549 cells in culture. Membrane damage to cells as assessed by trypan blue exclusion increased with increasing concentration of bacteria. After 45 min of incubation with 7.5 × 10⁸ bacteria/ml less than 20% of A549 cells excluded trypan blue. The lytic activity of S. pneumoniae was inhibited by phosphatidylcholine liposomes containing cholesterol. Using an haemolysis assay and S. pneumoniae's culture filtrates, the efficiency of the anti-lytic activity of liposomes was found to be distearoylphosphatidylcholine (DSPC) > dipalmitoylphosphatidylcho-line (DPPC) > dimyristoylphosphatidylcholine (DMPC). Furthermore, the anti-lytic activity also depended on the cholesterol content in a non-trivial manner. There was no protection against haemolytic activity at cholesterol content of less than 20% for DSPC and 35 mole% for DPPC and DMPC liposomes respectively. Above these threshold values inhibition of lytic activity increased sharply. In agreement with the haemolysis results, A549 cells were protected by liposomes against the lytic activity of S. pneumoniae with the efficiency also being DSPC > DPPC > DMPC. Clearly the efficiency of liposomal cholesterol is increased with increasing gel to liquid crystalline phase transition temperature of the lipid matrix. The results suggest that liposomal cholesterol may be used to protect the host against cell damage caused by S. pneumoniae.     

Improved Encapsulation of DNA in pH-Sensitive Liposomes for Transfection

Abstract

A simple method has been developed to prepare liposomes containing large amounts of DNA. The procedure consisted of three cycles of freeze-thawing a mixture of sonicated liposomes and DNA. The encapsulation efficiency depended on the size of DNA. For a small plasmid (2.7 kb), approximately 40% of input DNA was entrapped with an efficiency of 16 μgDNA/μmol lipid. For larger plasmids, the encapsulation efficiency decreased considerably. Transfection of cultured mouse L929 cells mediated by the DNA-containing liposomes was assayed with a plasmid containing the E. coli chloramphenicol acetyl transferase gene. The transfection activity of the liposome was primarily determined by its pH sensitivity. Acid-sensitive liposomes transfected cells efficiently, whereas pH-insensitive liposomes were much less active. The level of the expression of the exogenous gene in the treated cells could be further modulated by protein kinase C (PKC) activators that were incorporated into the liposomal membrane as a minor lipid component. Transfection conditions were optimized with respect to DNA, lipid, and PKC activator concentrations. The results of the current study may help the use of liposomal delivery system for applications in gene therapy.     

Release of Active Drug from Intracellular Liposomal Prodrug Depots in Macrophages Controlled by Liposome Composition

Abstract

Several drugs have limited potency due to their rapid elimination or inactivation. The anticancer drug 5-fluoro-deoxyuridine (FUdR), which is frequently used in therapeutic treatment of liver metastases from colon tumors, is an example of such drugs. It is rapidly eliminated from circulation and metabolized, mainly by the hepatocytes in the liver. Over the past few years we have investigated the possibility to keep the drug away from the hepatocytes and to save it from rapid inactivation by encapsulating it in liposomes. In this way the liposomal drug is expected to accumulate in the macrophages of the liver (Kupffer cells), which form a major target site for intravenously administered liposomes. There, as the liposomal structure is gradually degraded by lysosomal enzymes, the drug will be released, initially within the lysosomal compartment, while subsequently it will leak out of the lysosomes and eventually out of the cells so as to become available for uptake by intrahepatically situated tumor cells. In this contribution we describe this system for the prodrug dipalmitoyl-FUdR, incorporated in the liposomal bilayer, requiring an additional step for the drug to become available, i.e. the enzymatic deacylation of the prodrug. It is demonstrated that the rate of intralysosomal degradation of liposomes in Kupffer cells varies substantially with liposomal lipid composition and that the rate of release of active drug from the Kupffer cells parallels the rate of liposome degradation. In addition, it is demonstrated that in this way the antitumor activity of the FUdR can be enhanced by more than two orders of magnitude and that the degree of antitumor activity reflects, to a limited extent, the rate at which the liposomes are degraded.     

Lipophilic prodrug conjugates allow facile and rapid synthesis of high-loading capacity liposomes without the need for post-assembly purification

Abstract

Dihydropyridopyrazoles are simplified synthetic analogues of podophyllotoxin that can effectively mimic its molecular scaffold and act as potent mitotic spindle poisons in dividing cancer cells. However, despite nanomolar potencies and ease of synthetic preparation, further clinical development of these promising anticancer agents is hampered due to their poor aqueous solubility. In this article, we developed a prodrug strategy that enables incorporation of dihydropyridopyrazoles into liposome bilayers to overcome the solubility issues. The active drug was covalently connected to either myristic or palmitic acid anchor via carboxylesterase hydrolyzable linkage. The resulting prodrugs were self-assembled into liposome bilayers from hydrated lipid films using ultrasound without the need for post-assembly purification. The average particle size of the prodrug-loaded liposomes was about 90?nm. The prodrug incorporation was verified by differential scanning calorimetry, spectrophotometry and gel filtration reaching maximum at 0.3 and 0.35 prodrug/lipid molar ratios for myristic and palmitic conjugates, respectively. However, the ratio of 0.2 was used in the particle size and biological activity experiments to maintain long-term stability of the prodrug-loaded liposomes against phase separation during storage. Antiproliferative activity was tested against HeLa and Jurkat cancer cell lines in vitro showing that the liposomal prodrug retained antitubulin activity of the parent drug and induced apoptosis-mediated cancer cell death. Overall, the established data provide a powerful platform for further clinical development of dihydropyridopyrazoles using liposomes as the drug delivery system.     

Animal Experiments—An Essential Component for the Development of Liposomal Anticancer Agents

The poor selectivity of anticancer drugs often leads to their multiplicate dose-limiting toxicities in humans, which severely restricts their clinical application. In this study, a novel liposomal formulation of zedoary turmeric oil (ZTO) targeting the insulin receptor (IR) was prepared by covalently conjugating insulin to the terminal of the polyethylene glycol (PEG) chain of sterically stabilized liposomes. In vitro assays indicated that a higher uptake of insulin-modified sterically stabilized liposomes (ISSLs) was observed in SMMC-7721 hepatocarcinoma cells overexpressing insulin receptors. IC₅₀ values of ISSLs, NTLs (nontargeted liposomes), and ZTO injection (free ZTO) against SMMC-7721, determined by MTT assays, were 157.2, 256.7, and 43.3?μg·ml^?1, respectively. Plasma-clearance profiles of ZTO in the liposomal formulations were then compared with that of ZTO injection. The liposomal formulations showed much longer terminal half-lives (11.24 and 14.73 hours for ISSLs and NTLs, respectively) than that of ZTO injection (1.45 hours). All results above indicated the ISSLs were potentially useful for the treatment of IR (+) tumors and are worthy of further investigation.     

Incorporation of dimethoxycurcumin into charged liposomes and the formation kinetics of fractal aggregates of uncharged vectors

Abstract

Dimethoxycurcumin (DMC) is a lipophilic analog of curcumin found in Curcuma longa Linn., which is known to possess significant activity against various cancer cell lines. The purpose of this study was to develop suitable liposomal formulations in order to overcome DMC’s poor water solubility and to study the aggregation kinetic profile using the fractal analysis. DMC was incorporated into liposomal formulations composed of DPPC, DPPC:DPPG:chol (9:1:1 molar ratio) and DPPC:DODAP:chol (9:1:1 molar ratio) liposomes. Light scattering techniques were used to elucidate the physicochemical parameters of the liposomal formulations with and without DMC. The structural characteristics of the incorporated molecule were found to be crucial and promote the aggregation mechanism depending also on the liposomes’ composition. The results of our study contribute to the overall scientific efforts to prepare efficient carriers for DMC and could be a useful tool in order to study more efficiently the kinetics of the aggregation process of the liposomal carriers.     

Targeting of Drugs to Solid Tumors Using Anti-Her2 Immunoliposomes

Abstract

Cancer therapy would clearly benefit from a carrier system capable of intracellular delivery of systemically administered drugs to cancer cells in solid tumors. Sterically stabilized immunoliposomes specific to the cells expressing HER2 protooncogene (anti-HER2 SIL), were designed by conjugating Fab’ fragments of a recombinant humanized anti-HER2 MAb to the distal termini of poly(ethylene glycol) chains on the surface of unilamellar liposomes (size 90–100 nm) of phosphatidylcholine, cholesterol, and poly (ethylene glycol)—derivatized phosphatidylethanolamine. Anti-HER2 SIL avidly and specifically bound to cultured HER2-overexpressing cancer cells (8,000–23,000 vesicles per cell) and became endocytosed (k_e = 0.022–0.033 min.^?1) via the coated pit pathway. Anti-HER2 SIL showed prolonged circulation lifetime in rats (blood MRT approx. 24 hours) and significantly increased antitumor activity of encapsulated doxorubicin against HER2-overexpressing human breast cancer xenografts in nude mice. Although the accumulation of anti-HER2 SIL in HER2-overexpressing tumor xenografts was not increased over that of non-targeted sterically stabilized liposomes (SL), microscopic examination revealed abundance of anti-HER2 SIL in the interstitial spaces, as well as within the cytoplasm of cancer cells, while identical liposomes lacking anti-HER2 Fab’ were located predominantly within tumor-resident macrophages. Anti-HER2 SIL, a targeted vehicle capable of in vivo intracellular delivery of substances to HER2-overexpressing solid cancers, enhances the potential for tumor targeting and opens new avenues for better treatment of cancer.     

Efficacy of Gel Formulations Containing free and Liposomal Foscarnet in a Murine Model of Cutaneous HSV-1 Infection

Abstract

The efficacy of gel formulations containing free and liposomal foscarnet has been evaluated in a murine model of cutaneous Herpes simplex virus type-1 infection. Both formulations were applied topically 3 times daily for 4 days and initiated 24 h post-infection. The penetration of liposomes incorporated into the gel in infected skin tissues was better than that of liposomes dispersed in buffer. Therein, their localization mostly matched that of viral antigen detected by immunoperoxydase staining. Despite these facts, the efficacy of gel formulations of both free and liposomal foscarnet in preventing the development of a zosteriform rash in mice was similar. Electron microscopic examination revealed that liposomes incorporated into the gel formed aggregates together with the micelles of gel. Diffusion studies showed that liposomes were trapped within these aggregates and were hardly able to diffuse across a polycarbonate membrane. In addition, although the liposomes were shown to be highly stable in vitro, the formation of these aggregates destabilized their membrane resulting in a premature release of foscarnet from liposomes. The efficacy of both gel formulations was higher than that of solutions of free or liposomal foscarnet suggesting that the gel formulation is a suitable matrix for the delivery of drugs. Thus, strategies aimed at reducing the interaction of liposomes with the gel could be a convenient approach to improve the efficacy of liposome-encapsulated drug over the free drug.     

Liposomes with Metronidazole for Topical Use: The Choice of Preparation Method and Vehicle

Abstract

Liposomes containing metronidazole were prepared for the treatment of skin disorder Rosacea. To optimize the composition and size of liposomes, natural and synthetic lipids were used in three different preparation methods. Optimal liposomal preparation was incorporated into five dermal vehicles (three O/W emulsion creams and two gels) and vehicles tested for the stability (at 20 and 40 °C) during a storage period of 4 weeks. The evaluation of the vehicles was based on the comparison between the original size distribution of liposomes and liposomes in vehicles (after 4 weeks) and on the rheological behaviour. The best vehicle appears to be the Carbopol? gel, in which the liposomal size stayed unchanged even at 40 °C during the 4 weeks period.     

Investigation of parameters influencing incorporation,retention and cellular cytotoxicity in liposomal formulations of poorly soluble camptothecin

Abstract

Improving tumor delivery of lipophilic drugs through identifying advanced drug carrier systems with efficient carrier potency is of high importance. We have performed an investigative approach to identify parameters that affect liposomes’ ability to effectively deliver lipophilic camptothecin (CPT) to target cells. CPT is a potent anticancer drug, but its undesired physiological properties are impairing its therapeutic use. In this study, we have identified parameters influencing incorporation and retention of lipophilic CPT in liposomes, evaluating the effect of lipid composition, lipid chemical structure (head and tail group variations, polymer inclusion), zeta potential and anisotropy. Polyethyleneglycol (PEG) surface decoration was included to avoid liposome fusing and increase the potential for prolonged in vivo circulation time. The in vitro effect of the different carrier formulations on cell cytotoxicity was compared and the effect of active targeting of one of the formulations was evaluated. We found that a combination of liposome surface charge, lipid headgroup and carbon chain unsaturation affect CPT incorporation. Retention in liposomes was highly dependent on the liposomal surroundings and liposome zeta potential. Inclusion of lipid tethered PEG provided stability and prevented liposome fusing. PEGylation negatively affected CPT incorporation while improving retention. In vitro cell culture testing demonstrated that all formulations increased CPT potency compared to free CPT, while cationic formulations proved significantly more toxic to cancer cells that healthy cells. Finally, antibody mediated targeting of one liposome formulation further enhanced the selectivity towards targeted cancer cells, rendering normal cells fully viable after 1 hour exposure to targeted liposomes.     

Liposomes as a Mucosal Adjuvant System: An Intranasal Liposomal Influenza Subunit Vaccine and the Role of IgA in Nasal Anti-Influenza Immunity

Abstract

Liposomes exhibit potent immunoadjuvant activity in a variety of experimental vaccine formulations. We have investigated the mucosal adjuvant activity of liposomes in an influenza subunit vaccine. Mice were immunized intranasally (I.N.) with the major surface antigen of influenza virus, hemagglutinin (HA), mixed with negatively charged liposomes. Inclusion of the liposomes in the vaccine resulted in a marked stimulation of the serum IgG response against the antigen. In addition, the liposomal preparation, but not the antigen alone, induced a significant secretory IgA (s-IgA) response, not only in the lungs and nasal cavity, but also at the mucosa of the urogenital tract. The adjuvant activity of the liposomes appeared to be independent of a physical association of the antigen with the liposomes: Stimulation of antibody responses was observed even when liposomes and antigen were administered separately in time. Serum IgG and local s-IgA responses to I.N. immunization with the liposomal vaccine were comparable to the corresponding responses induced by an influenza infection. Mice immunized with the liposomal vaccine or mice recovered from an influenza infection were completely protected from (re)infection. Protection from nasal infection was abrogated by treatment of the mice with an anti-IgA antiserum, while anti-IgG had no effect, indicating that s-IgA plays an essential role in nasal anti-influenza immunity.     

Caprylate-Conjugated Cisplatin for the Development of Novel Liposomal Formulation

Cisplatin, first (platinum) compound to be evolved as an anticancer agent, has found its important place in cancer chemotherapy. However, the dose-dependent toxicities of cisplatin, namely nephrotoxicity, ototoxicity, peripheral neuropathy, and gastrointestinal toxicity hinder its widespread use. Liposomes can reduce the toxicity of cisplatin and provide a better therapeutic action, but the low lipid solubility of cisplatin hinders its high entrapment in such lipid carrier. In the present investigation, positively charged reactive aquated species of cisplatin were complexed with negatively charged caprylate ligands, resulting in enhanced interaction of cisplatin with lipid bilayer of liposomes and increase in its encapsulation in liposomal carrier. Prepared cisplatin liposomes were found to have a vesicular size of 107.9 ± 6.2 nm and zeta potential of −3.99 ± 3.45 mV. The optimized liposomal formulation had an encapsulation efficiency of 96.03 ± 1.24% with unprecedented drug loading (0.21 mg cisplatin / mg of lipids). The in vitro release studies exhibited a pH-dependent release of cisplatin from liposomes with highest release (67.55 ± 3.65%) at pH 5.5 indicating that a maximum release would occur inside cancer cells at endolysosomal pH. The prepared liposomes were found to be stable in the serum and showed a low hemolytic potential. In vitro cytotoxicity of cisplatin liposomes on A549 lung cancer cell line was comparable to that of cisplatin solution. The developed formulation also had a significantly higher median lethal dose (LD₅₀) of 23.79 mg/kg than that of the cisplatin solution (12 mg/kg). A promising liposomal formulation of cisplatin has been proposed that can overcome the disadvantages associated with conventional cisplatin therapy and provide a higher safety profile.Key Words: cisplatin, complexation, cytotoxicity, LD₅₀, liposome     

Liposomes loaded with a dirhenium compound and cisplatin: preparation,properties and improved in vivo anticancer activity

Abstract

Liposomes loaded with the rhenium compound (bis-dimethylsulfoxido-cis-tetrachlorodi-μ-pivalatodirhenium(III) (cis–Re₂((CH₃)₃CCOO)₂Cl₄?2DMSO, I) and cisplatin in the molar ratio of 4:1 as well as those loaded only with I were synthesized and characterized by scanning electron microscopy, transmission electron microscopy, dynamic light scattering and electronic absorption spectroscopy. The relative stability of liposomes loaded with I is reflected by a minimal change in the electronic absorption spectra over a period of 8 days whereas the stability of those loaded with both drugs is lower, which we ascribe to the formation of new Re-Pt species inside the liposomes. Furthermore, the investigations of the co-encapsulation effects on the anticancer activity of the Re-Pt system were undertaken. Importantly, the co-encapsulated liposomes exhibit synergistic or additive anticancer activities in vivo, e.g. introduction of these liposomes into tumor-bearing rats demonstrated their antianemic, nephro- and hepato-protecting effects. These liposomes, which are active in cancer treatment, protect the dirhenium compounds from hydrolysis and preserve the biological properties of the Re-Pt hybrid. This study reveals the importance of combined therapy in nanotechnology and medicine.     

Novel Camptothecin Analogue (Gimatecan)‐Containing Liposomes Prepared by the Ethanol Injection Method

Small‐sized liposomes have several advantages as drug delivery systems, and the ethanol injection method is a suitable technique to obtain the spontaneous formation of liposomes having a small average radius. In this paper, we show that liposomal drug formulations can be prepared in situ, by simply injecting a drug‐containing lipid(s) organic solution into an aqueous solution. Several parameters should be optimized in order to obtain a final suitable formulation, and this paper is devoted to such an investigation. Firstly, we study the liposome size distributions determined by dynamic light scattering (DLS), as function of the lipid concentration and composition, as well as the organic and aqueous phases content. This was carried out, firstly, by focusing on POPC (1‐palmitoyl‐2‐oleoyl‐sn‐glycero‐3‐phosphocholine) then on the novel L‐carnitine derivative PUCE (palmitoyl‐(R)‐carnitine undecyl ester chloride), showing that it is possible to obtain monomodal size distributions of rather small vesicles. In particular, depending on the conditions, it was possible to achieve a population of liposomes with a mean size of 100 nm, when a 50 mM POPC ethanol solution was injected in pure water; in the case of 50 mM PUCE the mean size was around 30 nm, when injected in saline (0.9% NaCl). The novel anticancer drug Gimatecan, a camptothecin derivative, was used as an example of lipophilic drug loading by the injection method. Conditions could be found, under which the resultant liposome size distributions were not affected by the presence of Gimatecan, in the case of POPC as well as in the case of PUCE. To increase the overall camptothecin concentration in the final liposomal dispersion, the novel technique of “multiple injection method” was used, and up to a final 5 times larger amount of liposomal drug could be reached by maintaining approximately the same size distribution. Once prepared, the physical and chemical stability of the liposome formulations was satisfactory within 24, as judged by DLS analysis and HPLC quantitation of lipids and drug. The Gimatecan‐containing liposomes formulations were also tested for in vitro and in vivo activity, against the human nonsmall cell lung carcinoma NCI‐H460 and a murine Lewis lung carcinoma 3 LL cell lines. In the in vitro tests, we did not observe any improvement or reduction of the Gimatecan pharmacological effect by the liposomal delivery system. More interestingly, in the in vivo Lewis lung carcinoma model, the intravenously administration of liposomal Gimatecan formulation showed a mild but significant increase of Tumor Volume Inhibition with respect to the oral no‐liposomal formulation (92% vs. 86 %, respectively; p < 0.05). Finally, our study showed that the liposomal formulation was able to realize a delivery system of a water‐insoluble drug, providing a Gimatecan formulation for intravenous administration with a preserved antitumoral activity.