Pegylated Liposomal Mitomycin C Lipidic Prodrug in Combination With External Beam Radiation Therapy in Patients With Advanced Cancer: A Phase 1B Study.

PURPOSE: The aim of this study was to evaluate a formulation of pegylated liposomal mitomycin C lipidic prodrug (PL-MLP) in patients concomitantly undergoing external beam radiation therapy (RT). METHODS AND MATERIALS: Patients with metastatic disease or inoperable primary solid tumors requiring RT for disease control or symptom relief were treated with 2 courses of PL-MLP (1.25, 1.5, or 1.8 mg/kg) at 21-day intervals, along with 10 fractions of conventional RT or 5 stereotactic body RT fractions initiated 1 to 3 days after the first PL-MLP dose and completed within 2 weeks. Treatment safety was monitored for 6 weeks, and disease status was re-evaluated at 6-week intervals thereafter. MLP levels were analyzed 1 hour and 24 hours after each PL-MLP infusion. RESULTS: Overall, 19 patients with metastatic (18) or inoperable (1) disease received combination treatment, with 18 completing the full protocol. Most patients (16) had diagnoses of advanced gastrointestinal tract cancer. One grade 4 neutropenia event possibly related to study treatment was reported; other adverse events were mild or moderate. Of the 18 evaluable patients, 16 were free of RT target lesion progression at first re-evaluation. Median survival of the entire patient population was 63.3 weeks. Serum MLP level correlated with dose increases and similar long circulating profiles were observed before and after RT. CONCLUSIONS: PL-MLP up to 1.8 mg/kg in combination with RT treatment is safe, with a high rate of tumor control. Drug clearance is not affected by radiation. PL-MLP is potentially an attractive option for chemoradiation therapy that warrants further evaluation in randomized studies in the palliative and curative settings.

Ex-vivo activation of a liposomal prodrug of mitomycin C by human tumors.

PURPOSE: To examine the ex- vivo ability of explanted human tumors and normal tissue to activate liposomal mitomycin C lipidic prodrug (MLP) by releasing the active free drug form, mitomycin C (MMC). METHODS: We tested conversion of MLP to MMC in an ex vivo assay using explanted tissues obtained during routine surgery to remove primary tumors or metastases. Tumor and adjacent normal tissue were obtained from freshly explanted tumors and were immediately deep frozen at - 70 °C. On test day, the fragments were thawed, homogenized and incubated in the presence of a fixed amount of liposomal MLP at 37 °C for 1 h. We measured MLP and its rate of conversion to MMC by HPLC. Controls included plasma, malignant effusions, red blood cells, tumor cell lines, mouse liver, and buffer with dithiothreitol, a potent reducing agent. RESULTS: Most patients tested (16/20) were diagnosed with colo-rectal carcinoma. The average fraction of MLP cleaved per 100-mg tumor tissue (21.1%, SEM = 1.8) was greater than per 100-mg normal tissue (16.6%, SEM = 1.3). When the tumor and normal tissue samples were paired by patient, the difference was statistically significant (p = 0.022, paired t test). Biological fluids did not activate liposomal MLP, while normal liver tissue strongly does. Interestingly, the omental fatty tissue also greatly activated MLP. CONCLUSIONS: Tumor tissue homogenates activate MLP with greater efficiency than the surrounding normal tissues, but far less than liver and adipose tissue. These observations demonstrate the bioavailability of liposomal MLP in human tumors, and its pharmacologic potential in cancer therapy.

Liposome co-encapsulation of anti-cancer agents for pharmacological optimization of nanomedicine-based combination chemotherapy.

Aim: Co-encapsulation of anti-cancer agents in pegylated liposomes may provide an effective tool to maximize efficacy of combined drug therapy by taking advantage of the long circulation time, passive targeting, and reduced toxicity of liposome formulations. Methods: We have developed several liposome formulations of co-encapsulated drugs using various permutations of three active agents: doxorubicin (Dox), mitomycin-C lipidic prodrug (MLP), and alendronate (Ald). Dox and MLP are available in single drug liposomal formulations: pegylated liposomal Dox (PLD, Doxil®), clinically approved, and pegylated liposomal MLP (PL-MLP, Promitil®), in phase 1-2 clinical testing. We have previously shown that co-encapsulation of Dox and Ald in pegylated liposomes (PLAD) results in a formulation with valuable immuno-pharmacologic properties and superior antitumor properties over PLD in immunocompetent animal models. Building on the PLAD and PL-MLP platforms, we developed a new pegylated liposomal formulation of co-entrapped Dox and MLP (PLAD-MLP), with the former localized in the liposome water phase via remote loading with an ammonium alendronate and the latter passively loaded into the liposome lipid bilayer. An alternative formulation of co-entrapped MLP and Dox in which ammonium Ald was replaced with ammonium sulfate (PLD-MLP) was also tested for comparative purposes. Results: PLAD-MLP displays high loading efficiency of Dox and MLP nearing 100%, and a mean vesicle diameter of 110 nm. Cryo-transmission electron microscopy (cryo-TEM) of PLAD-MLP reveals round vesicles with an intra-vesicle Dox-alendronate precipitate. PLAD-MLP was tested in an in vitro MLP activation assay with the reducing agent dithiothreitol and found to be significantly less susceptible to thiolytic activation than PL-MLP. Alongside thiolytic activation of MLP, a significant fraction of encapsulated Dox was released from liposomes. PLAD-MLP is stable upon in vitro incubation in human plasma with nearly 100% drug retention. In mouse pharmacokinetic studies, PLAD-MLP extended MLP half-life in circulation when compared to that of MLP delivered as PL-MLP. In addition, the MLP levels in tissues were greater than those obtained with PL-MLP, indicating that PLAD-MLP slows down the cleavage of the prodrug MLP to MMC, thus resulting in a more sustained and prolonged exposure. The circulation half-life of Dox in PLAD-MLP was similar to the PLD Dox half-life. The pattern of tissue distribution was similar for the co-encapsulated drugs, although Dox levels were generally higher than those of MLP, as expected from cleavage of MLP to its active metabolite MMC. In mouse tumor models, the therapeutic activity of PLAD-MLP was superior to PL-MLP and PLD with a convenient safety dose window. The Ald-free formulation, PLD-MLP, displayed similar pharmacokinetic properties to PLAD-MLP, but its therapeutic activity was lower. Conclusion: PLAD-MLP is a novel multi-drug liposome formulation with attractive pharmacological properties and powerful antitumor activity and is a promising therapeutic tool for combination cancer chemotherapy.

Development of Promitil®, a lipidic prodrug of mitomycin c in PEGylated liposomes: From bench to bedside.

Several liposome products have been approved for the treatment of cancer. In all of them, the active agents are encapsulated in the liposome water phase passively or by transmembrane ion gradients. An alternative approach in liposomal drug delivery consists of chemically modifying drugs to form lipophilic prodrugs with strong association to the liposomal bilayer. Based on this approach, we synthesized a mitomycin c-derived lipidic prodrug (MLP) which is entrapped in the bilayer of PEGylated liposomes (PL-MLP, Promitil®), and activated by thiolytic cleavage. PL-MLP is stable in plasma with thiolytic activation of MLP occurring exclusively in tissues and is more effective and less toxic than conventional chemotherapy in various tumor models. PL-MLP has completed phase I clinical development where it has shown a favorable safety profile and a 3-fold reduction in toxicity as compared to free mitomycin c. Clinical and pharmacokinetic studies in patients with advanced colo-rectal carcinoma have indicated a significant rate of disease stabilization (39%) in this chemo-refractory population and significant prolongation of median survival in patients attaining stable disease (13.9 months) versus progressive disease patients (6.35 months). The pharmacokinetics of MLP was typically stealth with long T½ (~1 day), slow clearance and small volume of distribution. Interestingly, a longer T½, and slower clearance were both correlated with disease stabilization and longer survival. This association of pharmacokinetic parameters with patient outcome suggests that arrest of tumor growth is related to the enhanced tumor localization of long-circulating liposomes and highlights the importance of personalized pharmacokinetic evaluation in the clinical use of nanomedicines. Another important area where PL-MLP may have an added value is in chemoradiotherapy, where it has shown a strong radiosensitizing effect in animal models based on a unique mechanism of enhanced prodrug activation and encouraging results in early human testing.

Pharmacokinetics of mitomycin-c lipidic prodrug entrapped in liposomes and clinical correlations in metastatic colorectal cancer patients.

Background Pegylated liposomal (PL) mitomycin-c lipidic prodrug MLP) may be a useful agent in patients with metastatic colo-rectal carcinoma (CRC). We report here on the pharmacokinetics and clinical observations in a phase 1A/B study with PL-MLP. Methods Plasma levels of MLP were examined in 53 CRC patients, who received PL-MLP either as single agent or in combination with capecitabine and/or bevacizumab. MLP was determined by an HPLC-UV assay, and its pharmacokinetics was analyzed by noncompartmental methods. The correlation between clinical and pharmacokinetic parameters was statistically analyzed. Results PL-MLP was well tolerated with a good safety profile as previously reported. Stable Disease was reported in 15/36 (42%) of efficacy-evaluable patients. Median survival of stable disease patients (14.4 months) was significantly longer than of progressive disease patients (6.5 months) and non-evaluable patients (2.3 months). MLP pharmacokinetics was stealth-like with long T½ (~1 day), slow clearance, and small volume of distribution (Vd). The addition of capecitabine and/or bevacizumab did not have any apparent effect on the pharmacokinetics of MLP and clinical outcome. High baseline neutrophil count and CEA level were correlated with faster clearance, and larger Vd. Stable disease patients had longer T½ and slower clearance than other patients. T½ and clearance were significantly correlated with survival. Conclusions PL-MLP treatment results in a substantial rate of disease stabilization in metastatic CRC, and prolonged survival in patients achieving stable disease. The correlation of neutrophil count and CEA level with pharmacokinetic parameters of MLP is an unexpected finding that needs further investigation. The association of long T½ of MLP with stable disease and longer survival is consistent with an improved probability of disease control resulting from enhanced tumor localization of long-circulating liposomes and underscores the relevance of personalized pharmacokinetic evaluation in the use of nanomedicines.

Folate receptor targeting of radiolabeled liposomes reduces intratumoral liposome accumulation in human KB carcinoma xenografts.

BACKGROUND: Active, ligand-mediated, targeting of functionalized liposomes to folate receptors (FRs) overexpressed on cancer cells could potentially improve drug delivery and specificity. Studies on folate-targeting liposomes (FTLs) have, however, yielded varying results and generally fail to display a clear benefit of FR targeting. METHOD: Tumor accumulating potential of FTLs and NTLs were investigated in a FR overex-pressing xenograft model by positron emission tomography/computed tomography imaging. RESULTS: Tumors displayed significantly lower activity of FTLs than NTLs. Furthermore, FTLs displayed worse circulating properties and increased liver-accumulation than NTLs. CONCLUSION: This study underlines that long-circulating properties of liposomes must be achieved to take advantage of EPR-dependent tumor accumulation which may be lost by functionalization. FR-functionalization negatively affected both tumor accumulation and circulation properties.

Targeting of folate-conjugated liposomes with co-entrapped drugs to prostate cancer cells via prostate-specific membrane antigen (PSMA).

Folate-targeted liposomes (FTL) were tested as drug delivery vehicles to PSMA-positive cancer cells. We used FL with co-entrapped mitomycin C lipophilic prodrug (MLP) and doxorubicin (DOX), and the LNCaP prostate cancer cell line which expresses PSMA but is negative for folate receptor. A major increase in cell drug levels was observed when LNCaP cells were incubated with FTL as compared to non-targeted liposomes (NTL). MLP was activated to mitomycin C, and intracellular and nuclear fluorescence of DOX was detected, indicating FTL processing and drug bioavailability. PMPA (2-(phosphonomethyl)-pentanedioic acid), a specific inhibitor of PSMA, blocked the uptake of FTL into LNCaP cells, but did not affect the uptake of FTL into PSMA-deficient and folate receptor-positive KB cells. The cytotoxic activity of drug-loaded FTL was found significantly enhanced when compared to NTL in LNCaP cells. FTL may provide a new tool for targeted therapy of cancers that over-express the PSMA receptor.

Characterization of Pegylated Liposomal Mitomycin C Lipid-Based Prodrug (Promitil) by High Sensitivity Differential Scanning Calorimetry and Cryogenic Transmission Electron Microscopy.

The effect of a lipidated prodrug of mitomycin C (MLP) on the membrane of a pegylated liposome formulation (PL-MLP), also known as Promitil, was characterized through high-sensitivity differential scanning calorimetry (DSC) and cryo-TEM. The thermodynamic analysis demonstrated that MLP led to the formation of heterogeneous domains in the membrane plane of PL-MLP. MLP concentrated in prodrug-rich domains, arranged in high-ordered crystal-like structures, as suggested by the sharp and high enthalpy endotherm in the first heating scanning. After thiolytic cleavage of mitomycin C from MLP by dithiothreitol (DTT) treatment, the crystal-like prodrug domain disappears and a homogeneous membrane with stronger lipid interactions and higher phase transition temperature compared with the blank (MLP-free) liposomes is observed by DSC. In parallel, the rod-like discoid liposomes and the "kissing liposomes" seen by cryo-TEM in the PL-MLP formulation disappear, and liposome mean size and polydispersity increase after DTT treatment. Both MLP and the residual postcleavage lipophilic moiety of the prodrug increased the rigidity of the liposome membrane as indicated by DSC. These results confirm that MLP is inserted in the PL-MLP liposome membrane via its lipophilic anchor, and its mitomycin C moiety located mainly at the region of the phospholipid glycerol backbone and polar headgroup. We hypothesize that π-π stacking between the planar aromatic rings of the mitomycin C moieties leads to the formation of prodrug-rich domains with highly ordered structure on the PL-MLP liposome membrane. This thermodynamically stable conformation may explain the high stability of the PL-MLP formulation. These results also provide us with an interesting example of the application of high sensitivity DSC in understanding the composition-structure-behavior dynamics of liposomal nanocarriers having a lipid-based drug as pharmaceutical ingredient.

Coencapsulation of alendronate and doxorubicin in pegylated liposomes: a novel formulation for chemoimmunotherapy of cancer.

We developed a pegylated liposome formulation of a dissociable salt of a nitrogen-containing bisphosphonate, alendronate (Ald), coencapsulated with the anthracycline, doxorubicin (Dox), a commonly used chemotherapeutic agent. Liposome-encapsulated ammonium Ald generates a gradient driving Dox into liposomes, forming a salt that holds both drugs in the liposome water phase. The resulting formulation (PLAD) allows for a high-loading efficiency of Dox, comparable to that of clinically approved pegylated liposomal doxorubicin sulfate (PLD) and is very stable in plasma stability assays. Cytotoxicity tests indicate greater potency for PLAD compared to PLD. This appears to be related to a synergistic effect of the coencapsulated Ald and Dox. PLAD and PLD differed in in vitro monocyte-induced IL-1ß release (greater for PLAD) and complement activation (greater for PLD). A molar ratio Ald/Dox of ∼1:1 seems to provide an optimal compromise between loading efficiency of Dox, circulation time and in vivo toxicity of PLAD. In mice, the circulation half-life and tumor uptake of PLAD were comparable to PLD. In the M109R and 4T1 tumor models in immunocompetent mice, PLAD was superior to PLD in the growth inhibition of subcutaneous tumor implants. This new formulation appears to be a promising tool to exploit the antitumor effects of aminobisphosphonates in synergy with chemotherapy.

Targeting of pegylated liposomal mitomycin-C prodrug to the folate receptor of cancer cells: Intracellular activation and enhanced cytotoxicity.

Mitomycin C (MMC) is a powerful anti-bacterial, anti-fungal and anti-tumor antibiotic, often active against multidrug resistant cells. Despite a broad spectrum of antitumor activity, MMC clinical use is relatively limited due to its fast clearance and dose-limiting toxicity. To exploit the potential antitumor activity of MMC and reduce its toxicity we have previously developed a formulation of pegylated liposomes with a lipophilic prodrug of MMC (PL-MLP), activated by endogenous reducing agents which are abundant in the tumor cell environment in the form of different thiols. PL-MLP has minimal in vitro cytotoxicity unless reducing agents are added to the cell culture to activate the prodrug. In the present study, we hypothesized that targeting PL-MLP via folate receptors will facilitate intracellular activation of prodrug and enhance cytotoxic activity without added reducing agents. We grafted a lipophilic folate conjugate (folate-PEG(5000)-DSPE) to formulate folate targeted liposomes (FT-PL-MLP) and examined in vitro cell uptake and cytotoxic activity in cancer cell lines with high folate receptors (HiFR). 3H-cholesterol-hexadecyl ether (3H-Chol)-radiolabeled liposomes were prepared to study liposome-cell binding in parallel to cellular uptake of prodrug MLP. 3H-Chol and MLP cell uptake levels were 4-fold and 9-fold greater in KB HiFR cells when FT-PL-MLP is compared to non-targeted PL-MLP liposomes. The cytotoxic activity of FT-PL-MLP liposomes was significantly increased up to ~5-fold compared with PL-MLP liposomes in all tested HiFR expressing cell lines. The enhanced uptake and intracytoplasmic liposome delivery was confirmed by confocal fluorescence studies with Rhodamine-labeled liposomes. In vivo, no significant differences in pharmacokinetics and biodistribution were observed when PL-MLP was compared to FT-PL-MLP by the intravenous route. However, when liposomes were directly injected into the peritoneal cavity of mice with malignant ascites of J6456 HiFR lymphoma cells, the tumor cell levels of MLP were significantly greater with the folate-targeted liposomes. Thus, folate targeting enhances liposome uptake by tumor cells enabling intracellular activation of prodrug in the absence of exogenous reducing agents, and leading to increased cytotoxicity. These results may be particularly relevant to the application of folate-targeted PL-MLP in intracavitary or intravesical treatment of cancer.

Pharmacologic Studies of a Prodrug of Mitomycin C in Pegylated Liposomes (Promitil(®)): High Stability in Plasma and Rapid Thiolytic Prodrug Activation in Tissues.

PURPOSE: Pegylated liposomal (PL) mitomycin C lipid-based prodrug (MLP) has recently entered clinical testing. We studied here the preclinical pharmacology of PL-MLP. METHODS: The stability, pharmacokinetics, biodistribution, and other pharmacologic parameters of PL-MLP were examined. Thiolytic cleavage of MLP and release of active mitomycin C (MMC) were studied using dithiothreitol (DTT), and by incubation with tissue homogenates. RESULTS: MLP was incorporated in the bilayer at 10% molar ratio with nearly 100% entrapment efficiency, resulting in a formulation with high plasma stability. In vitro, DTT induced cleavage of MLP with predictable kinetics, generating MMC and enhancing pharmacological activity. A long circulation half-life of MLP (10-15 h) was observed in rodents and minipigs. Free MMC is either extremely low or undetectable in plasma. However, urine from PL-MLP injected rats revealed delayed but significant excretion of MMC indicating in vivo activation of MLP. Studies in mice injected with H3-cholesterol radiolabeled PL-MLP demonstrated relatively greater tissue levels of H3-cholesterol than MLP. MLP levels were highest in tumor and spleen, and very low or undetectable in liver and lung. Rapid cleavage of MLP in various tissues, particularly in liver, was shown in ex-vivo experiments of PL-MLP with tissue homogenates. PL-MLP was less toxic in vivo than equivalent doses of MMC. Therapeutic studies in C26 mouse tumor models demonstrated dose-dependent improved efficacy of PL-MLP over MMC. CONCLUSIONS: Thiolytic activation of PL-MLP occurs in tissues but not in plasma. Liposomal delivery of MLP confers a favorable pharmacological profile and greater therapeutic index than MMC.

Pegylated liposomal mitomycin C prodrug enhances tolerance of mitomycin C: a phase 1 study in advanced solid tumor patients.

Mitomycin C (MMC) has potent cytotoxicity but cumulative toxicity limits widespread use. In animals, pegylated liposomal mitomycin C lipid-based prodrug (PL-MLP) was well tolerated and more effective than free MMC. We evaluated PL-MLP in patients with advanced cancer. Twenty-seven patients were treated in escalating dose cohorts of 0.5-3.5 mg/kg (equivalent to 0.15-1.03 mg/kg MMC) every 4 weeks for up to 12 cycles, unless disease progression or unacceptable toxicity occurred. Pharmacokinetics were assessed during cycles 1 and 3. Per protocol maximum tolerated dose was not reached at 3.5 mg/kg. However, prolonged thrombocytopenia developed after repeated doses of 3 mg/kg or cumulative doses of 10-12 mg/kg. Dose-related grade 3 or higher adverse events included fatigue, anemia, and decreased platelets. Cmax and AUC0-∞ increased linearly over the dose range 0.5-2.0 mg/kg, and greater than linearly from 2.5 to 3.5 mg/kg; there were no significant differences in clearance of MLP between cycles 1 and 3. Median t1/2 was 23 h among dose cohorts, with no trend by dose or cycle. One patient had a partial response. Stable disease was observed in 10 patients across all dose levels. PL-MLP has a long circulation time, was well tolerated, and can be administered to heavily pretreated patients at a single dose of 3.0 mg/kg and cumulative dose of 10-12 mg/kg before development of prolonged thrombocytopenia; this is nearly threefold the equivalent dose of MMC tolerated historically. This formulation may be active in a variety of tumor types and is better tolerated than free MMC.

Liposome encapsulation of zoledronic acid results in major changes in tissue distribution and increase in toxicity.

BACKGROUND: Zoledronic acid (Zol) is a potent inhibitor of farnesyl-pyrophosphate synthase with broad clinical use in the treatment of osteoporosis, and bone metastases. We have previously shown that encapsulation of Zol in liposomes targeted to the folate receptor (FR) greatly enhances its in vitro cytotoxicity. To examine whether targeted liposomal delivery of Zol could be a useful therapeutic approach, we investigated here the in vivo pharmacology of i.v. administered liposomal Zol (L-Zol) in murine models. METHODS: Zol was passively entrapped in the water phase of liposomes containing a small fraction of either dipalmitoyl-phosphatidylglycerol (DPPG) or a polyethylene-glycol (PEG)-conjugated phospholipid with or without insertion of a folate lipophilic conjugate. Radiolabeled formulations were used for pharmacokinetic (PK) and biodistribution studies. Toxicity was evaluated by clinical, hematological, biochemical, and histopathological parameters. Therapeutic studies comparing free Zol, nontargeted and folate targeted L-Zol were performed in FR-expressing human tumor models. RESULTS: Encapsulation of Zol in liposomes resulted in major PK changes including sustained high plasma levels and very slow clearance. DPPG-L-Zol was cleared faster than PEG-L-Zol. Grafting of folate lipophilic conjugates on liposomes further accelerated the clearance of Zol. L-Zol caused a major shift in drug tissue distribution when compared to free Zol, with a major increase (20 to 100-fold) in liver and spleen, a substantial increase (7 to 10-fold) in tumor, and a modest increase (2-fold) in bone. Liposomal formulations proved to be highly toxic, up to 50-fold more than free Zol. PEG-L-Zol was more toxic than DPPG-L-Zol. Toxicity was non-cumulative and appears to involve macrophage/monocyte activation and release of cytokines. Co-injection of L-Zol with a large dose of blank liposomes, or injection of a very low Zol-to-phospholipid ratio liposome formulation reduced toxicity by 2-4-fold suggesting that diluting macrophage exposure below a threshold Zol concentration is important to overcome toxicity. L-Zol failed to significantly enhance the therapeutic activity of Zol vis-à-vis free ZOL and doxorubicin. Folate-targeted L-Zol was marginally better than other treatment modalities in the KB tumor model but toxic deaths greatly affected the outcome. CONCLUSIONS: Liposome delivery of Zol causes a major change in tissue drug distribution and an increase in tumor Zol levels. However, the severe in vivo toxicity of L-Zol seriously limits its dose and its utility for in vivo tumor cell targeting. This strategy is under evaluation using liposomes carrying less toxic bisphosphonates.

Therapeutic efficacy of a lipid-based prodrug of mitomycin C in pegylated liposomes: studies with human gastro-entero-pancreatic ectopic tumor models.

BACKGROUND: A mitomycin-C lipid-based prodrug (MLP) formulated in pegylated liposomes (PL-MLP) was previously reported to have significant antitumor activity and reduced toxicity in mouse tumor models (Clin Cancer Res 12:1913-20, 2006). MLP is activated by thiolysis releasing mitomycin-C (MMC) which rapidly dissociates from liposomes. The purpose of this study was to examine the plasma stability, pharmacokinetics, and antitumor activity of PL-MLP in mouse models of human gastroentero-pancreatic tumors. METHODS: MLP was incorporated with almost 100% efficiency in pegylated liposomes composed of hydrogenated phosphatidylcholine, with or without cholesterol (Chol). Mean vesicle size was 45-65 nm for liposome preparations downsized by homogenization, and 80-100 nm when downsized by extrusion, the latter displaying narrower polydispersity. MLP to phospholipid mole ratio was 5% (~20 µg MMC-equivalents/µmol). Therapeutic studies were carried out in the N87 gastric carcinoma (Ca), HCT15 colon Ca, and Panc-1 pancreatic Ca models implanted s.c. in CD1 nude mice. Treatment was administered i.v. in mice with established tumors. RESULTS: PL-MLP was very stable when incubated in plasma, and whole blood with a maximum of 5% release and activation to free MMC after 24 h. In the presence of a strong reducing agent (dithiotreitol), MLP was almost entirely activated to free MMC. Pharmacokinetic studies revealed major differences in plasma clearance between free MMC and PL-MLP. The longest half-lives were observed for extruded and Chol-containing preparations. Using a liposome radiolabel, it was found that the plasma levels of liposomes and prodrug were nearly superimposable confirming the absence of drug leakage in circulation. In vivo prodrug activation was significantly increased by co-injection of a large dose of a biocompatible reducing agent, N-acetylcysteine. PL-MLP was significantly more effective in delaying tumor growth and resulted in more tumor regressions than irinotecan in the N87 and HCT15 models, and than gemcitabine in the Panc-1 model. PL-MLP was ~3-fold less toxic than free MMC at MMC-equivalent doses, and displayed mild myelosuppression at therapeutic doses. CONCLUSIONS: Delivery of MLP in pegylated liposomes is more effective than conventional chemotherapy in the treatment of gastroentero-pancreatic ectopic tumor models, and may represent an effective tool for treatment of these malignancies in the clinical setting with improved safety over free MMC. Reducing agents offer a tool for controlling in vivo prodrug release.

Delivery of zoledronic acid encapsulated in folate-targeted liposome results in potent in vitro cytotoxic activity on tumor cells.

INTRODUCTION: Zoledronic acid (ZOL), a nitrogen-containing bisphosphonate, is a potent inhibitor of farnesyl-pyrophosphate synthase with poor in vitro cytotoxic activity as a result of its limited diffusion into tumor cells. The purpose of this study was to investigate whether liposomes targeted to the folate receptor (FR) can effectively deliver ZOL to tumor cells and enhance its in vitro cytotoxicity. METHODS: ZOL was entrapped in the water phase of liposomes of various compositions with or without a lipophilic folate ligand. Stability and blood levels after i.v. injection were checked. The in vitro cytotoxic activity and cell uptake of liposomal ZOL (L-ZOL) were examined on various human and mouse cell lines. RESULTS: All formulations were highly stable and resulted in high blood levels in contrast to free ZOL which was rapidly cleared from plasma. Non-targeted L-ZOL was devoid of any in vitro activity at concentrations up to 200 microM. In contrast, potent cytotoxic activity of folate-targeted L-ZOL (FTL-ZOL) was observed, with optimal activity, reaching the sub-micromolar range, for dipalmitoyl-phosphatidylglycerol (DPPG)-containing liposomes and relatively lower activity for pegylated (PEG) formulations. IC50 values of FTL-ZOL on FR-expressing tumor cells were >100-fold lower than those of free ZOL. Compared to doxorubicin, the cytotoxicity of DPPG-FTL-ZOL was equivalent in drug-sensitive cell lines, and greatly superior in drug-resistant cell lines. When tested on the non-FR upregulated cell lines, the cytotoxicity of FTL-ZOL was lower but still superior to that of L-ZOL. The uptake of ZOL by FR-expressing tumor cells was enhanced approximately 25-fold with DPPG-FTL-ZOL, and only approximately 4-fold with PEG-FTL-ZOL. CONCLUSIONS: FR targeting of ZOL using liposomes is an effective means to exploit the tumor cell growth inhibitory properties of ZOL. DPPG-FTL-ZOL is significantly more efficient at intracellular delivery of ZOL than PEG-FTL-ZOL in FR-expressing tumor cells.

Improved therapeutic activity of folate-targeted liposomal doxorubicin in folate receptor-expressing tumor models.

PURPOSE: The folate receptor (FR) is overexpressed in a broad spectrum of malignant tumors and represents an attractive target for selective delivery of anti-cancer agents to FR-expressing tumors. Targeting liposomes to the FR has been proposed as a way to enhance the effects of liposome-based chemotherapy. METHODS: Folate-polyethylene glycol-distearoyl-phosphatidyl-ethanolamine conjugate was inserted into pegylated liposomal doxorubicin (PLD). The therapeutic activity of folate-targeted (FT-PLD) and non-targeted (PLD) pegylated liposomal doxorubicin was tested in two human tumor models (KB, KB-V) and in one mouse ascitic tumor model (FR-expressing J6456) by the i.v. systemic route in all models, and by the i.p. intracavitary route in the ascitic tumor model only. RESULTS: Consistent with previous studies, PLD was clearly superior to free doxorubicin in all tumor models. When targeted and non-targeted liposome formulations were compared, FT-PLD was more effective than PLD in the KB and KB-V xenograft models, and in the J6456 intra-cavitary therapy model. The therapeutic effect was dose-dependent in the KB model and schedule-dependent in the J6456 intra-cavitary therapy model. In some experiments, toxic deaths aggravated by folate-depleted diet were a major confounding factor. In a non-FR expressing J6456 model, FT-PLD was as active as PLD indicating that its activity is not limited to FR-expressing tumors. CONCLUSION: Folate-targeting confers a significant albeit modest therapeutic improvement to PLD in FR-expressing tumor models, which appears particularly valuable in intracavitary therapy. The potential clinical added value of this approach has yet to be determined.

Acetylcholinesterase inhibitors and cholinergic modulation in Myasthenia Gravis and neuroinflammation.

The cholinergic network affects various cellular functions including neurotransmission, and immune reactions. In Myasthenia Gravis (MG), diagnosis and symptomatic therapy are based on cholinergic modulation by acetylcholinesterase inhibitors (AChEI). In Alzheimer's disease (AD) a neurodegenerative disorder associated with inflammatory pathology, cholinergic systems cell loss occurs early. Treatments with special AChEI enhance cholinergic transmission and may act as anti-inflammatory agent via immunocompetent cells expressing alpha-7 acetylcholine receptor (AChR). In Multiple Sclerosis (MS) an inflammatory T-cell-mediated disease, demyelination and neurodegeneration follow neuroinflammation. MS treatment includes anti-inflammatory and immunomodulatory drugs. AChEI can induce cholinergic up-regulation with subsequent effect on neuroinflammation via alpha-7-AChR expressing cells. These effects are additional to the cognitive benefit induced by AChEI.

Stimulated-single fiber electromyography monitoring of anti-sense induced changes in experimental autoimmune myasthenia gravis.

The neuromuscular weakness associated with myasthenia gravis (MG) can be transiently relieved by pharmacological inhibitors of acetylcholinesterase (AChE). Here, we expand the anticholinesterase repertoire to include 2'-O-methyl-protected antisense oligonucleotides targeted to AChE mRNA (EN101). Using stimulated-single fiber electromyography, we show that EN101 treatment of rats with experimental autoimmune myasthenia gravis (EAMG), improved the mean consecutive difference (MCD) and blocking for 24h. This treatment was more efficient than pyridostigmine and was accompanied by marked improvement in stamina and clinical profile.

Anti-inflammatory properties of cholinergic up-regulation: A new role for acetylcholinesterase inhibitors.

We investigated the anti-inflammatory effects of acetylcholinesterase inhibitors (AChEI) at the cellular and molecular levels. AChEI suppressed lymphocyte proliferation and pro-inflammatory cytokine production, as well as extracellular esterase activity. Anti-inflammatory activity was mediated by the alpha7 nicotinic acetylcholine receptor (neuronal); the muscarinic receptor had the opposite effect. Treatment of the central nervous system (CNS) inflammatory disease, experimental autoimmune encephalomyelitis (EAE), with EN101, an anti-sense oligodeoxynucleotide, targeted to AChE mRNA, reduced the clinical severity of the disease and CNS inflammation intensity. The results of our experiments suggest that AChEI increase the concentration of extracellular acetylcholine (ACh), rendering it available for interaction with a nicotinic receptor expressed on lymphocytes. Our findings point to a novel role for AChEI which may be relevant in CNS inflammatory diseases such as EAE and multiple sclerosis. They also emphasize the importance of cholinergic balance in neurological disorders, such as Alzheimer's disease and myasthenia gravis, in which these drugs are used.

The role of readthrough acetylcholinesterase in the pathophysiology of myasthenia gravis.

Alternative splicing induces, under abnormal cholinergic neurotransmission, overproduction of the rare "readthrough" acetylcholinesterase variant AChE-R. We explored the pathophysiological relevance of this phenomenon in patients with myasthenia gravis (MG) and rats with experimental autoimmune MG (EAMG), neuromuscular junction diseases with depleted acetylcholine receptors. In MG and EAMG, we detected serum AChE-R accumulation. In EAMG, we alleviated electromyographic abnormalities by nanomolar doses of EN101, an antisense oligonucleotide that selectively lowers AChE-R in blood and muscle yet leaves unaffected the synaptic variant AChE-S. Whereas animals treated with placebo or conventional anticholinesterases continued to deteriorate, a 4 wk daily oral administration of EN101 improved survival, neuromuscular strength and clinical status in moribund EAMG rats. The efficacy of targeting only one AChE splicing variant highlights potential advantages of mRNA-targeted therapeutics for chronic cholinergic malfunctioning.